DE1499144B2 - SELF-SUPPORTING WRAP PACK MADE OF THREAD OR TAPE-SHAPED GOOD - Google Patents

Description

The invention relates to a self-supporting winding package made of thread-like or band-shaped material, which after a A series of figures representing 8 is wound around the winding package, the points of intersection are angularly offset, with a continuous axial opening that has a cylindrical central part and its intermediate parts on both sides with decreasing diameter, in particular of spherical shape, as well as end parts that expand outward. The thread-like or ribbon-like material can be different Be kind; it can e.g. B. made of fibers, yarn, threads, cord, tape, strips, wire or narrow plastic sheets exist. In particular, it can consist of flexible materials that have a smooth surface and / or have unusual elongation properties or which only have a low surface pressure may be exposed. The thread-like or ribbon-like material should be properly removed from the winding package let unwind.

In a winding pack of the above type (US Pat. No. 30,61238), the inner walls of the form widening end parts each have a cone shell. Such wraps are not yet in full Dimensions inherently durable.

The invention is based on the object of providing a winding package made of thread-like or band-like material create which in and of itself is with certainty durable, so that the good either comes from within or can be freely withdrawn from the outside or from a radial opening.

This object is achieved according to the invention in that, in a winding package, the initially called type the inner walls of the widening end parts are curved around centers that are outside of the winding package and in the vicinity of its plane of symmetry running in the transverse direction.

The advantages of the invention are in particular that in such a winding pack the inner Windings do not coincide because this is an expansion of the material to a larger layer would be required. The wrapping pack does not collapse on the outside either, presumably because of the tension inside the property that results from the above-mentioned position of the center points and the resulting containment effect follows.

The aforementioned effect can either be achieved by doing the special with a spindle Shape is worked or in that the inner layers of the coil is given a corresponding shape and the winding is then carried out on these inner layers.

In the drawing, exemplary embodiments of the subject matter of the invention are shown. It shows

1 shows a machine for producing a winding package according to the invention in a schematic representation,

ίο F i g. 2 a spindle of the machine according to FIG. 1 in the Front view, with the spindle designed for a coil with "one" turn without lead, F i g. 3 the spindle according to FIG. 2 in side view,

F i g. 4 and 5 winding packs according to the invention in an axial section and

F i g. 6 shows an end of a spindle in which the material extends over 180 ° around the spherical end, in the side view.

Fig. 1 shows schematically the basic form of a machine for winding flexible material according to the invention. Such a machine has a spindle corresponding to the inner shape of the winding package with a central part 12 or 12 ′, intermediate parts 14 and end parts 16 . Correspondingly, the winding package has a middle part 162, intermediate parts 164 and end parts 166 (FIGS. 4, 5). The middle part is cylindrical (12) or shaped like a curve (12 '). The intermediate parts 14 have the shape of spherical surfaces, and the end parts 16 adjoin these.

A material guide 18 for the flexible material moves generally parallel to the spindle axis. The cylindrical central part 12 is used when the material guide 18 is moving at a constant speed, as is customary in machines of the type under consideration here. The curved central part 12 'adapts the spindle to a crank movement or a movement with constant acceleration. In such a machine, means are provided to change the following variables: firstly the ratio of the speed of the spindle to the number of reciprocations of the material guide 18, secondly the length of the path of the material guide and thirdly the distance of the material guide from the spindle axis. Each of these variables depends on the speed of the spindle or the number of back and forth movements of the material guide 18 or on a measuring instrument which determines and responds to the various lengths of the wound material. If a cylindrical or conical spindle is used on such a machine instead of the specially designed spindle, the wound material slips out at the ends of the winding when the material guide 18 reverses its movement and especially when it is in a plane outside that of the spindle directly opposite area moved back and forth. This phenomenon can be avoided if the diameter of the spindle in the reversal area of the material guide 18 is reduced. However, the extent of the reduction in the diameter of the spindle, the length over which this reduction takes place, and the ratio of these two variables to the length of the path of the material guide 18 and to the distance of the material guide from the axis of rotation determine the diameter and the Ratio with which it is wrapped.

In practice, it should be noted that, although in the winding machines the material guide 18 is opposite to the central part 12 of the spindle or the corresponding

Middle part 162 of the winding package moves generally at constant speed, the reversal time at the ends of its path is very different. This is due to the fact that the material guide 18 does not arrive at full speed at the end of its path and immediately reverses, but reduces its speed to a standstill, in order to then increase it again to the previous dimension while the spindle continues its rotation uniformly . This reversal time of the material guide 18 is not only dependent on the shape of the curve which controls its back and forth movement, but also on the type and accuracy of fit of the connecting means via which the movement is transmitted to the material guide 18 and to the rotating spindle. The reversal time can vary as a function of the degree of rotation, the operating speed (revolutions per minute) and the setting of the lanyard. A simple method of recording this turnaround time for any type of machine is to attach a spring to the material guide 18 and record a trail of ink on a paper roll rotating at approximately the intended operating speed. The degree length of the approximately straight (vertical) reversal part of the ink trail represents the reversal time.

The basic forms of an ideal system and the setting required for an inversion time of 15.3 ° is required are shown in FIGS. 2 and 3 shown.

The reversal time or the length of the dwell time of the material guide 18, measured in a length measure, is directly proportional to the wound diameter. This means, as the reversal start line AX and reversal end line AM in FIG. 2 show, which show the reversal length for each diameter of the system, that the reversal time and the reversal path always correspond to the same angular path for each diameter that is being wound. The method depends on five parameters, firstly the distance of the material guide 18 from the axis, secondly the length of the path of the material guide, thirdly the radius of the spindle to be wound, fourthly the ratio of the speed of the spindle including the lead to the number of outward movements. and events of the material guide and, fifthly, the reversal time of the material guide and the connecting means. In certain cases, some secondary quantities, which are inherently dependent quantities, can be used, and the aforementioned primary quantities can be determined from them. If z. B. the size of the winding angle is prescribed, the length of the path of the material guide 18 is determined from it. A certain winding system belongs to each individual group of sizes.

The basic shape of the spindle, which is shown in FIG. 3 is shown for a winding package with "one" turn with Leading zero determined. It can be for leading (plus or minus) turns and for turns of a order number other than "one" can be changed, however, as it is, for plus-minus- "one" - Turns are used.

In the case of a winding system, the "basis" is that phase or that radius which corresponds to half the distance between the material guide 18 and the axis. This is important because it determines a central point, the throat point 17 ', through which the two curves at the spindle ends pass, which define the shape of the inwardly widening ends 16 and 166 of a spindle or winding package, starting from zero is wound to the maximum with a material guide 18 moving in one plane.

The front view (FIG. 2) of such a spindle and its system is constructed as follows, with most of the points that are decisive for the side view (FIG. 3) resulting: First, the 0-degree-180-degree line AA and drawn the 90-degree-270-degree line BB . Then the axis A is marked. At 57.5 °, the angle whose tangent is n / 2 , the straight lines Α-Fund AG are drawn, which delimit 180 ° of the circumference of the spindle on each plane that runs vertically between them, the radius of which is equal to the horizontal distance is the plane from axis A. Then the cylinder // is drawn with the radius R% (or r) (Fig. 2). Then the straight line / - / is drawn as a tangent to the circle H , which reflects its developed half of the circumference. From the axis A , the straight line AL defining the material guide 18 is drawn at 60 °. Where it meets the level / - / at L , it indicates the distance of the material guide 18 from the axis, and in this way the largest radius of the system, the circle O. The straight lines Α-Fund AG intersect the straight line / - / at U and V.

Since the system shown is intended to be set up for a machine with a reversal time Y of 15.3 °, a point X is located halfway through a corresponding distance, ie at a distance of approximately 7.65 °, calculated in degrees of the radius Rb or r "(Fig. 2), on the developed circumference of the circle // in the plane above the point L and a point M in half of this distance below. To design the inversion system in a way that comes close to the ideal, X the point taken by the material guide 18 when its deceleration begins. L denotes half the path of the material guide 18 during the reversing time, and M denotes the end of the reversing path. Then the straight line AX is drawn. On the plane / - / there is the point K is the length of the reversal time below the zero degree point C.

At the distance AV over V, the 180 ° point, point Di is drawn, which represents the ideal point determining the changes, which is 16.7 ° over AD . As a future drawing aid, the straight line A-Di-60 is drawn (which intersects the straight line FG, the tangent to the circle O ), which graphically shows the length of the change between itself and AD for each ideal basic shape drawn in the side view. Then point S is determined, a point that determines the change, at a distance of three quarters of the return path above Di.

In order to design the basic shape of the spindle, the side view is then drawn with the symmetry line C, the axis A, the circumferential lines of the cylinder H, the upper straight line R and the lower straight line R \. Then the straight lines 61, 62 and 61 ' and 62' are drawn, which reflect the selected length of the path of the material guide 18.

In order to determine where the spherical surfaces of the intermediate parts 14 and 14 'approach the cylinder //, the straight winding line 92 in FIG. 3 is drawn by projecting the point K at 97 onto the line of symmetry C and the point X onto the straight lines 61, 62 and 61 ', 62' at 9 and 9 '. By connecting the point 97 and 9 or 9 ', the straight winding line 92 becomes

5 6

obtain. Then point S (at a distance of Ή λ width of the material will be moved radially outwards,

of the reversal path above Di) is projected over to which is to be wrapped in each case. In practice, the

on 92 to determine point 26, d. H. the point where winding process, that of the basic shape shown

the straight line of wind over the spherical surface is likely to be somewhat irregular

goes. Then the connecting line% will play vertically 5 because of the setting of the

drawn through this point and a corresponding advance in proportion to that of the others

Just 96 'on the opposite side. Where these elements of the winder is not entirely correct

Lines meet the axis A , are the centers and because of some other factors. Hence will

for some of the spherical turns to be represented by circles, perhaps the decreasing radius

Surfaces of the intermediate parts 14 and 14 '. io fill in something so that possibly in some positions

The throat point 17, 17 ', up to which the slightly less than 180 ° on the spherical surface or wound material is wound on the spherical surfaces according to the egg-shaped shapes that moves out of the outside, are determined by the points and spherical surface have been derived. In G (F i g. 2), which represent the zero-degree and 180 ° points in most cases, however, there will still be the greatest possible wrapped circumference, as points 15 free wrapped packages, which are 101 on the line of symmetry C and 24 on the straight line 61, enclosing and constricting effects and 62 are projected over. Points 24 and 101 have the resulting durability,
are connected by straight line 25. The straight line 25 Since a turn gains considerable durability, denotes a chord angle that is characteristic of the system if only part of it is of the shape shown. It represents a tendon within the approaching 20, it is possible to also represent the material on a spherical surface. A straight line through 26 parallel simple cylinders, slotted for easy removal, to the straight line 25 (in the example shown, the wrap where the Material guide 18 in one two straight line together) determines the throat points considerable distance from the axis is 17, 17 and 17 ', 17' where they are the spherical surfaces and he is approached step by step to the axis when the intermediate parts 14 and 14 'cuts. It determines the winding diameter increases. This also the angle, which is constant for all tendons, procedure can be continued until the material guides run accordingly in the system and that for rer 18 touches the surface of the coil, after which any basic shape can be used to which can be withdrawn, to determine flat ends instead of corresponding throat points. Build up by expanding the ends. The approach of throat points 17 and 17 ', throat lines 18a and 30 of the material guide can also be interrupted 18a' to become the basic shape of the spindle, while the winding package is built up in the illustrated manner, but in one way

Although the tolerances when winding according to this basic wound shape instead of a special one

Procedures are quite large, it is advisable to post shaped spindle.

Possibility of taking advantage of the process using 35 spindles that are smaller than the basic shape

to make the throat points for all diameters of the designed for the same system on a schematic basis

System and end parts of the type shown or with the help of test developments

to use. genes can be constructed on smaller cylinders if

In the case of the spindle according to FIG. 3, the end part 16 becomes through the spherical surfaces with the same change

set a curve, which are arranged in the point 23 of their 40 of 16.7 °.

Center has. This is at the same distance F i g. 4 shows a winding pack that is

from the point 19, which is designed at a distance that is equal to the measure. It is with a usual universal

Half of the largest reversal path is made below the winding machine, but in such a way that the

Point 13 is in which the line of symmetry C moves with material guide 18 on a fixed straight line,

the axis A intersects, and from the throat point 17'45 this winding package has a central axial opening

as well as from the point 20 ', which is there below the on with a cylindrical central part 162 with itself in the

Point 27 'is where the circumferential line R2 (Fig. 3) of the cross-section outwardly reducing intermediate parts

largest cylinder O intersects the straight line 6t ', 62'. 164 and with outwardly widening end parts

In FIG. 3, the center 23 would obviously be 166.

lie outside the drawing, namely where 50 F i g. FIG. 5 shows a winding package which is produced on a machine which extends the straight lines 23a and 236 (FIG. 3), in which cutting by changing. The axial radius of the end part should be slightly smaller than that of the largest cylinder, or the relative speed of the spindle and material, since it can additionally produce a radial opening 170 otherwise it can collide with the material guide 18. is through which the inner end of the material

If such end pieces 16 are used, there are 55 can be peeled off. The axial opening has

there are no more failures, the failure of the same shape as in the coil of FIG. 4th

Material avoided by putting it at each end of the. Such a coil can also be alternated with

Spindle or winding package is aligned, and plus and minus windings are made,

flawless, inherently durable wrap packs as in FIG. 6, the material 101 built up at 102 occurs even if a very smooth and under very 60 on the spherical surface of the intermediate part 14 of the

low tension material to be processed via spindle and exiting it at 103, being on its way

and the machine parts are already loose. The spherical intermediate part extends over an angle

End forms should extend by more than 180 ° when adjusted.

For this purpose 3 sheets of drawings

Claims (1)

Claim: Self-supporting wrapping package made of thread-like or band-shaped material, which is wound up according to a series of figures representing an 8, the points of intersection of which are angularly offset on the wrapping package, with a continuous axial opening that has a cylindrical central part and, on both sides, intermediate parts with decreasing dimensions Diameter, in particular of spherical shape, as well as end parts which widen outwards, characterized in that the inner walls of the widening end parts (166) are curved around center points which are outside the winding package and in the vicinity of its plane of symmetry running in the transverse direction (C) Because of.