DE19639588C2 - Method for setting the needle stroke of an electromagnetic needle selection device of a knitting machine - Google Patents

Description

The invention relates to a method for adjusting the needle stroke electromagnetic needle selection device of a knitting machine, wherein Selection elements when operating the knitting machine via the needle selector can be moved, and wherein the needle selector with Means is provided, when moving the selection elements over the Na delselection device generate electrical signals.

Electronic needle selection devices for knitting machines are known. You are u. a. realized by so-called selection blocks, the moveable che anchor on corresponding board elements of the knitting machine act. These selection blocks have the disadvantage that a switching process is very difficult takes a long time and the selection must therefore take place on several levels, which doesn't make the machines very compact. With increasing Ma line speed, more and more selection levels are necessary, which makes the necessary selection blocks increasingly expensive.

Methods have always been sought that make selection faster (possible at most on one level) and the selection elements can become smaller.

From DE 36 14 220 C1 it is known to use a needle selection device a measuring head for detecting the magnetic field in the control pole richly provided. This is done by an electrical circuit between  the measuring head and the control coil depending on the measurement result influenced.

In addition, a selection device is known from DE 44 42 405 C1, the permanent magnets and coils for controlling selection elements ten of the knitting machine. The selection elements become the end Voting facility offered via lock curves, from the permanent magnet held against a restoring force and by the control coils by reducing the magnetic forces either released or at no reduction in forces.

The adjustment effort required for the Selekti to function safely onsystems is considerable.

The invention has for its object the adjustment of an electromagnetic simplify the needle selection device of a knitting machine and to inexpensively design such a needle selection device.

This object is achieved in that the control coil for signal formation is used.

Advantageous embodiments of the invention are in claims 2 to 4 specified.  

Advantageous embodiments of the invention are in claims 2 to 5 specified.

The advantages achieved by the invention are in particular that the assembly of the selection system in a knitting machine with reduced and thus less expensive effort can be realized. An out exchange of the selection system, e.g. B. after a defect of the same can be carried out in the simplest way by non-specialists. One on agile manual assembly is eliminated.

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

Fig. 1 shows a needle selection system with support portions 2 and 3 Selekti onsbereichen,

Fig. 2, the needle selection system in top view,

Fig. 3 the provision of the selection elements of the selection system,

Fig. 4 is an enlarged view of FIG. 3,

Fig. 5, the induced voltage in the coil of the selection system and the needle stroke of the control computer,

Fig. 6 shows the induction voltage in the coil of the selection system and the needle clock of the control computer. Fig. 5 at deju stiertem selection system,

Fig. 7a, 7b, the basic arrangement of the selection system and the Se selection elements in a knitting machine, and

Fig. 8 shows the induction voltages of all three coils of the selection system and the needle clock of the control computer.

In Figs. 1 and 2, a selection system is illustrated in various views 9. It has two holding areas 1 a, 1 b and three selection areas 2 a, 2 b, 2 c. These areas are magnetically attractive by means of permanent magnets, which are not shown in more detail here, and the selection areas can be influenced in their magnetic strength by control coils.

In Fig. 3, the operation of the selection system 9 is shown, wherein magnetizable board parts 3 a to 3 i (so-called. Selection elements) of a knitting machine by means of a supply curve 4 are brought into contact with the holding areas of the selection system. The selection elements be because of themselves in the direction of arrow A. A resetting force acts on the selection elements, e.g. B. a spring force that moves the selection elements away from the holding or selection areas (wants to move away). Due to the magnetic force of the holding or selection areas, however, the selection elements are held on the selection system.

When the coil of a selection area is energized, the magnetic holding force is reduced to such an extent that the restoring force can move the selection element away from the selection system. (cf. selection element 3 h in FIG. 3 or FIG. 4)

Due to the different positions of the selection elements 3 a to 3 i the knitting needles of a knitting machine in different positions (z. B. Pos. 2 = 1 = not knitting knitting, Pos.) Brought.

Fig. 4 shows an enlarged section of the selection system 9 with the selection elements 3 a- 3 i of Fig. 3. As can be seen readily, the position of the selection elements in relation to the selection areas 2 a- 2 c must be known very precisely in order to Initiate energization of the control coil at the right time so that the desired selection element (e.g. selection element 3 e by energizing the coil from selection area 2 a) can be selected.

The control signals for the coils are usually controlled by a control computer generated, the distance of the signals by the mechanical Distance between the selection elements is determined. (Needle stroke)

The mechanical installation of the selection system must be carried out so that the energization of the coils of the selection areas always acts on the selection element to be selected. Should z. B. Selection element 3 e in Fig. 4 are selected by energizing the coil of the selection area 2 a, the selection system 9 must be installed in the position shown and must not be moved by a path in the direction of the arrow Y ben, otherwise the selection element 3 e not or even a wrong selection element (e.g. the selection element 3 d) when the selection system is shifted by a needle stroke.

The correct positioning is usually carried out in that put the knitting machine into operation and then the selection system like this is shifted long until a predetermined by the control computer Knitting pattern is knitted correctly.

On the other hand, it can also be provided that the sequence of the control pulses of the computer varied by manual settings on the computer so long until the control impulses are in the correct position for the selection system sen and thus a correct knitting is guaranteed.

Both types of adjustment are extremely complex.

As can be seen above, the position of the Selek must be a control computer tion elements in relation to the location of the selection areas, so that the currents in the coils are controlled correctly.  

Permanent magnets and coils are present in the selection system, whereby when moving the selection elements across the selection system the magnetic flux is changed and voltages in the coils indu be decorated.

The voltage 5 of a coil is shown in the diagram in FIG. 5, the needle clock 6 generated by the control computer also being shown. Each of the local minimum 7 a of the curve represents the entry of a selection element into the selection area of the selection system and each maximum 7 b represents the exit from this area.

By comparing the positions of needle cycle 6 , minimum 7 a and maximum 7 b, the control computer is able to determine the exact time of the selection information (FIGS . 4, 3e to 2a) for each selection element of the knitting machine in a table save and use for later operation.

With this measurement, the control computer knows the relative position of each selection element to the selection area of the selection system and is therefore capable of mounting and accuracy of the selection system on the one hand, and on the other hand also incorrectly positioned selection elements (e.g. slight mechanical deflections etc.) due to the timing of the control pulses (Needle cycle 6 ) for each selection element.

A complex mechanical adjustment of the selection system in a fixed correct position on the knitting machine is omitted. Mechanical tolerances Regarding the location of the selection elements of a knitting machine Control computer recognized and by adjusting the selection times compared.

Counting the minimum 7 a or maximum 7 b enables the control computer to control the number of selection elements. In FIG. 6, are missing at the points 8, the pronounced minima so that it can be concluded that no selection element of the knitting machine has passed the selection area of the selection system. If a lack of selection elements is excluded as the cause, the cause is an incorrect installation of the selection system.

In Fig. 7a and Fig. 7b shows the basic arrangement of a selection element 10, a spring 11 for generating a restoring force, a Anbietkurve 12 and a Justageadapters 13 is a Selektionssy stems 9, shown for the selection system. If the selection system is not correctly adjusted, some selection elements cannot be retained by the selection system due to the restoring force and return to the starting position (position . After the offer (transition of the selection element 10 from position 14 in FIG. 7a to position 15 in FIG. 7b) 14 of Fig. 7a) back, which is then expressed by the missing minima ( Fig. 6, 8). A mechanical cal adjustment of the selection system must take place until the control computer detects a behavior according to FIG. 5.

The selection system 9 has, for example, three selection regions 2 a- 2 c. In FIG. 8, the induction voltages are 16 a, 16 b, 16 of all three coils of the selection areas c shown. On the basis of the positions of the minima 17 , it can be determined at which local positions the selection areas of the selection system are located. This enables the control computer to identify production-related fluctuations in the locations of the selection areas and to correctly control the coils of the selection areas by adjusting the selection times for the selection elements, which reduces the tolerance requirements on the selection system and thus reduces production costs. The minima 18 a, 18 b, and 18c represent the sequential passage of the same selection element through the three selection areas of the selection system. The distances 19 a and 19 b are a measure of the position of the selection areas of the selection system.

In the above description it was assumed that the already existing control coils of the selection system are used to generate the induction voltages 5 , 16 a- 16 c. However, it can also be provided that separate coils, Hall elements or similar means are provided in / on the selection system to generate these voltages.

Claims (4)

1. A method for setting the needle clock of an electromagnetic needle selection device of a knitting machine, wherein Selectionsele elements are moved during operation of the knitting machine via the needle selection device, and wherein the needle selection device is provided with means which generate electrical signals when the selection elements are moved via the needle selection device, characterized in that that the control coil is used for signal generation. 2. The method according to claim 1, characterized in that
that the signals are fed to a control computer and their shape and distances are stored,
that the stored signals with the pulses of Nadeltak tes ( 6 ) of the computer are compared, and
that the sequence of the pulses of the needle clock ( 6 ) is varied by the computer until the position of the pulses of the needle clock to the signals ( 5 , 16 a- 16 c) is in a defined temporal and local position to each other. 3. The method according to claim 1, characterized in that a separate coil is used for signal formation.   4. The method according to claim 1 or 2, characterized in that the accuracy of the adjustment from the signal ( 5 , 16 a- 16 c) is derived abge.