EP1026297B1 - Method for representing patterns on inhomogeneous weaving grids - Google Patents

Abstract

A weaving pattern for non-uniform warp (12,22,32,42,52,62) and weft (10,20,30,40,50) with an irregular crossing point grid (a1 to a4, b1 to b3) uses a homogenous virtual grid with greater resolution. The crossing points on the virtual grid which correspond to real crossing points are determined and used to show the pattern.

Description

The invention relates to a method for pattern display on inhomogeneous intersection grids in the field of textile design.

The take-off of conventional weaving machines is done via gear drives controlled, with one change being about another Thread density through appropriate exchange of gear sets is carried out. Looms have been available for some time now, where the goods are deducted e.g. via stepper motors (or other controllable motors) is controlled what the Handling significantly simplified, now with a change no change to other gears must, but only the electrical control of the stepper motors will be changed. In addition, the stepper motor drive new benefits are available because it is - unlike at the "rigid" gear drive - possible, a variable Control the stepper motors so that the density the weft threads can be changed during the weaving process.

A textile designer sets the binding points when designing a pattern firmly, that is, the crossing points between warp and weft threads. This is done with the help of the so-called binding cartridge, the graphic representation of a weave on checkered Special paper (cartridge paper), or on corresponding Check raster images on a computer monitor. In which Cartridge paper changes depending on the fabric quality (warp and weft thread density) the number of diamonds in height and width. Now with a conventional weaving machine, as soon as this is set, the warp and weft basic density is constant. In a loom with stepper motor drive, as above explained, but the weft thread density in operation continually, i.e. also several times and differently, be changed. This leads to the difficulty that the Designers no longer display a pattern on cartridge paper can, so with a homogeneous grid of the same checks (because with a change in density, a corresponding diamond change should be done). This problem does not matter whether Cartridge paper or a corresponding monitor display is used.

In other words, the pattern designer can use the new freedoms the design caused by changes in thread density basically stepper motor driven weaving machines opened will not use at all because it is the weave cannot represent with associated pattern.

With this knowledge, the present invention starts with which a procedure is to be made available which can be used to represent patterns for fabrics at which the warp and / or weft density changes. The change in thread density can result in a change the number of threads per unit length, in a change of Thread thickness or thickness of one or more threads, or one Combination of such measures exist.

The task is accomplished through a process with the characteristics of Claim 1 solved; advantageous embodiments of the Invention are specified in the subclaims.

Fig.1

eine pixelorientierte Raster- oder Karodarstellung entsprechend herkömmlichem Patronenpapier, wobei die Kettfadendichte (in Richtung "a") gleich der Schußfadendichte (in Richtung "b") ist (quadratische Karos beim Patronenpapier);

Fig.2

eine Fig. 1 entsprechende Darstellung, wobei die Kettfadendichte größer als die Schußfadendichte ist (rechteckige Karos im Patronenpapier);

Fig. 3

ein inhomogenes reales Verkreuzungsraster zwischen Kettfäden 12, 22,..., 62 und Schußfäden 10, 20, ..., 50;

Fig. 4A und 4B

ein Handtuch mit drei Frottierabschnitten F1, F2, F3 und zwei Borten B1, B2 sowie einem über die Frottierabschnitte und die Borten reichenden Muster S bzw. S1-S5; und

Fig. 5

einen Ausschnitt aus einem virtuellen homogenen Punktraster, das zur Überlagerung des in Fig. 3 dargestellten realen inhomogenen Verkreuzungsrasters verwendet wird und eine wesentlich höhere Auflösung als dieses aufweist.

The invention is explained in more detail below on the basis of exemplary embodiments shown in the drawings, from which further advantages and features result. It shows:

Fig.1

a pixel-oriented raster or checker representation corresponding to conventional cartridge paper, the warp thread density (in direction "a") being equal to the weft thread density (in direction "b") (square checks in cartridge paper);

Fig.2

a representation corresponding to FIG. 1, the warp thread density being greater than the weft thread density (rectangular checks in the cartridge paper);

Fig. 3

an inhomogeneous real crossover pattern between warp threads 12, 22, ..., 62 and weft threads 10, 20, ..., 50;

4A and 4B

a towel with three terry sections F1, F2, F3 and two borders B1, B2 and a pattern S or S1-S5 reaching over the terry sections and the borders; and

Fig. 5

a section of a virtual homogeneous point grid, which is used to superimpose the real inhomogeneous crossing grid shown in FIG. 3 and has a much higher resolution than this.

1 shows several examples (three oblique lines, a wavy line, an open and a filled circle) a conventional diamond grid made of the same square Diamonds shown; this corresponds to the usual drawing programs. 2 shows a representation better adapted to the textile design, where rectangular squares are used corresponding to a different thread density in warp and Weft direction. Both in Fig. 1 and in Fig. 2 corresponds to the diamond grid with the crossing points homogeneous in the pattern, which means that all diamonds are the same. When changing the thread density by converting one conventional weaving machine changes the shape of the check corresponding.

Fig. 3 shows an inhomogeneous real crossing grid as greatly enlarged small section. Here is an example shown a case in which a weaving machine with stepper motor drive changes the thread density during operation. Here, warp threads 12, 22, 32, 42, 52 and 62 run in Vertical direction "a" and wefts 10, 20, 30, 40, and 50 in the horizontal direction "b". The actual crossing points are marked with dots. The resulting inhomogeneous Crossing grid is determined by the respective pitch spacing fixed and is shown in dashed lines.

While conventional, as shown in Figs. 1 and 2, all Checks are the same, this is with an inhomogeneous crossing grid 3 is no longer the case. Are exemplary in Fig. 3, indicated by hatching, three different ones Checks highlighted and denoted by I, II and III. From Fig. 3 it is also clear that different from each other Warp thread densities a1, a2, a3, a4 and different from each other Weft thread densities b1, b2, b3 are present.

It becomes obvious that a real inhomogeneous Intersection grid, as shown in a highly simplified manner in FIG. 3 is no pattern. This will be with the 4A, 4B illustrates the tissue in which a towel with three terry sections F1, F2 and F3 acts from each other by braids B1, B2 Flat fabrics are separated. As a simple example of a Pattern is an oblique strip S in Fig. 4A shown the different tissues (on the one hand F1-F3, on the other hand crosses B1, B2). Conventionally, the Towel shown in Fig. 4A the terry sections F1-F3 designed separately from the borders B1, B2 and then the different ones Control data for the loom in a control file composed.

For a loom with stepper motor drive would now be the design of the towel is possible in one operation, whereby at the transition from a terry section, such as F1, to the subsequent one Border B1 the thread density is changed. The problem that then arises for the designer Fig. 4B: because of the change in thread density (accordingly a change of the "check" in the conventional representation) however, the pattern (S in FIG. 4A) no longer corresponds to that desired shape, such as from the jump between the pattern sections S1 and S2 becomes clear. This could be the case with one as simple a pattern as a strip S or S1-S5 in Fig. 4A, 4B can still be compensated for more complicated Patterns, as are common in textile design, would be perfect impossible. The design would also be impossible if the thread density in a certain area several times erratic or even continuous, i.e. from thread to thread, changes. Therefore, according to the invention, as in the claim 1 is specified, initially an inhomogeneous real Intersection grid specified and this then a homogeneous virtual dot grid overlaid with significantly higher resolution. The corresponding homogeneous virtual grid is schematic shown in Fig. 5 and is considerably "finer", ie higher resolution than the corresponding real inhomogeneous grid 3.

Then, as in FIG. 5, using the one crossing point II of Fig. 3 illustrates the points of the virtual homogeneous grid of points found that one to Pattern-related intersection of the inhomogeneous real Meet intersection grid.

The pattern design is therefore done after the real tissue given by the inhomogeneous real intersection grid at the level of the virtual homogeneous intersection grid. The level of the real inhomogeneous intersection grid is with the level of the virtual homogeneous intersection grid connected by a corresponding mathematical transformation, making changes in the one level corresponding changes result in the other level.

The pattern design in the virtual homogeneous level enables hence the pattern representation in the usual, coherent Form, and implementation in reality, that is the concrete tissue takes place in the real inhomogeneous plane.

Claims (4)

1. Method for pattern representation on inhomogeneous crossing grids of warp and weft yards, in which

   a) an inhomogeneous real crossing grid is predetermined based on the real warp yarn density and the real weft yarn density;

   b) a homogenous virtual point grid with considerably increased resolution is overlaid onto the inhomogeneous real crossing grid;

   c) a pattern is represented in the homogenous virtual point grid; and

   d) those points of the virtual homogenous point grid are determined which coincide with crossing points of the real inhomogeneous crossing grid of the pattern.
2. Method according to claim 1, wherein between neighboring points of the virtual homogenous point grid interpolation is performed.
3. Method according to claim 2, wherein the interpolation is based on a small point group which belongs to a single crossing point of the inhomogeneous real crossing grid.
4. Method according to claim 3, wherein the neighboring point groups are connected by conjoined smaller point groups.

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