DE102014109295B3 - Coil with wave-shaped joining edges - Google Patents

Abstract

A coil (10) for receiving wound-up rod material, which is composed of two coil halves (12, 14), each coil half (12, 14) having a core portion (16, 18) and the core portions (16, 18) in the connected state forming the core of the bobbin (10), characterized in that each core section (16, 18) has an inner joining edge (26) and an outer joining edge (28) radially adjacent thereto for resting on a corresponding inner or outer joining edge (26, 28) ) of the other core section (18 or 16), which rotate around the core section (16, 18) in a wave-like manner, the shaft of the inner joining edge (26) being out of phase with respect to the shaft of the outer joining edge (28) in such a way that there is a sequence in the direction of rotation formed inwardly and outwardly stepped wall portions (30, 32), each of which inwardly stepped wall portion (32) of a core portion (16 or 18) in the connected state with an outwardly stepped Wandabschnit t (30) of the associated core section (18 or 16) overlaps, and in that the overlapping wall sections (30, 32) are latched together by snap connections, each comprising a projection (34) formed on one of the two overlapping wall sections (30 ), and a projection receiving recess (36) in the other wall portion (32).

Description

The present invention relates to a coil for receiving wound-up strand material, which is composed of two coil halves, each of which coil halves has a core portion and the core portions in the connected state form the core of the coil.

Such coils are known in numerous embodiments, for example DE 20 2008 005 926 U1 , They are used to accommodate a wound strand, such as cables, wires, tapes or the like, which are wound on the core of the coil. The core is usually closed at its axial ends by flanges axially delimiting the winding area around the core. It is divisible into two core sections, which are assigned to the respective coil halves. The divisibility of the coil is advantageous for various reasons. For example, the coil halves may be formed so that they can be stacked on each other in the disassembled state of the coil and thus well stored and transported.

DE 201 18 783 U1 discloses a reel spool formed of two bobbins glued together, the abutment surfaces extending radially, preferably in the middle of the winding core, and the connecting region alternately formed on the bobbins adhesive tabs which engage in corresponding pockets of the other bobbin. To increase the contact pressure acting on the contact surfaces of the connection region, the coil formers are positively and non-positively connected with each other.

DE 38 10 967 A1 discloses a winding spool whose winding width can be changed continuously. For this purpose, the core is subdivided transversely to the longitudinal axis, wherein the one part of the one flange and the other part is rotatably associated with the other flange, wherein the free end faces of each part lie on top and at the same distance from the longitudinal axis with a slope in the direction of the longitudinal axis, such in that they each have at least one discontinuity, wherein the one end face has a gradient corresponding to the other end face, but has an opposite slope, and wherein the flanges are held centered relative to the longitudinal axis.

To use the coil, the two coil halves must be assembled and securely connected together, in such a way that assembly errors are avoided, but at the same time accidental release of the coil halves is prevented from each other. For this purpose various locking connections or the like have been proposed variously, but these requirements do not always reliably meet.

Another problem is that the conventional coils are separated along a dividing plane, on which the respective connecting means are arranged on the coil halves. Accordingly, the joint line extends between the core portions in the circumferential direction just around the core and is also in a plane which is perpendicular to the coil axis. Along this joint line, the strand can easily pinch between the bobbin halves, which can lead to disturbances in the winding or unwinding of the strand material.

Object of the present invention is therefore to provide a divisible coil of the type mentioned, the halves of which are to be connected by advanced connecting means such that a secure hold of the coil halves to each other and a simple assembly are equally guaranteed. Another object of the present invention is to develop such a coil such that an undesirable clamping of the material to be stranded between the coil halves is avoided as possible.

This object is achieved by a coil having the features of claim 1.

In the coil according to the invention, each of the core sections to be joined has two joining edges on its outer circumference, namely an inner joining edge and an outer joining edge, which run around the core section. Each of these joining edges is intended to rest in the assembled state of the coil on the corresponding joining edge of the other core portion, d. h., In the assembled state, the inner joining edge of a bobbin half rests on the inner joining edge of the other bobbin half and the outer joining edge of one bobbin half rests on the outer joining edge of the other bobbin half. The inner joining edge and the outer joining edge encircle the core section in a wave-shaped manner, the shaft of the inner joining edge being out of phase with respect to the shaft of the outer joining edge. Thus, a maximum shaft of the outer joining edge coincide with a wave minimum of the inner joining edge, such that the outer joining edge in this peripheral region of the core portion projects beyond the inner joining edge and an inwardly stepped, d. h., Is formed on its radially inner side lower wall portion. Conversely, where a maximum of the wave of the inner joining edge meets a minimum of the shaft of the outer joining edge, an outwardly stepped wall portion can be formed. Outwardly and inwardly stepped wall sections alternate due to the periodicity of the waves of the joint edges in the circumferential direction.

The core sections can be joined together by being axially offset from one another and each overlapping an inwardly stepped wall section of a core section with an outwardly stepped wall section of the associated core section such that the inner and outer wall sections complement one another to form a shell portion of the core. This overlapping can be achieved by first placing the joining edges of the two core sections out of phase with each other and then rotating the core sections against each other such that the maxima and minima coincide and the joining edges sliding towards one another during the rotation are finally matched. The process described above during twisting applies equally to the inner and outer joining edges of the two core sections.

The finally overlapping wall sections are latched together by snap connections. These each comprise a projection which is provided on one of the two overlapping wall sections, that is to say approximately on the outside of an outwardly stepped wall section. In the corresponding overlapping wall sections, ie in the present example on the inside of the inwardly stepped wall portion, a corresponding recess is present, which receives this projection when the joining edges are stacked in the final rotational position. It is understood that the respective wall sections for this latching connection can have a certain elasticity, so that they can yield slightly inward or outward during screwing in to overlap the wall sections in order to allow the projection to slide on the inner surface of the respective other wall section can until he reaches the recess.

The wave course of the joining edges is expediently to be selected so that the superjacent joining edges can easily slide on one another during the rotational movement.

According to a preferred embodiment of the present invention, the waves of the inner and outer joint edges are sine waves.

Further preferably, the projections and recesses are formed approximately lens-shaped.

According to a further preferred embodiment of the invention, each core portion has an approximately cylindrical or conical jacket whose wall is bounded axially in the direction of the other core portion on the inside of the shell by the inner joining edge and on the outside of the shell by the outer joining edge.

According to a further preferred embodiment of the present invention, each coil half comprises a flange whose outer edge has an arcuate cross-section. As a result, the outer edge acquires a certain resilience against hard impacts, in particular in the radial direction. Damage to the outer edge of the flange can thus be prevented if necessary.

Further preferably, the arcuate cross section of the outer edge is reinforced on its inside by radial ribs.

In the following a preferred embodiment of the present invention will be explained in more detail with reference to the drawing.

1 is an exploded perspective view of an embodiment of the coil according to the invention;

2a - 2d are partial views of the connecting region of the two coil halves of the coil 1 in different rotational positions of the coil halves to each other;

3 is a side view of the coil 1 ;

4 is a perspective view of the coil 1 in the assembled state; and

5 and 6 are detailed views of the coil out 4 ,

The sink 10 out 1 serves to accommodate wound-up strand material, such as cables, wires or the like. It is composed of two coil halves, of which the in 1 upper bobbin half with the reference numeral 12 is designated and the lower coil half with the reference numeral 14 , Each of the coil halves 12 . 14 includes a core section 16 . 18 , and the core sections 16 . 18 let out the in 1 assembled position in the axial direction and interconnect by means of a rotary motion, as will be explained in more detail below. The terms "axial" and "radial" are used herein and in the following description and in the claims to refer to the axis of rotation of the coil, which in 1 is vertical. Likewise, the terms "inside" and "outside" are intended to refer to the radial direction, ie, to a direction away from or toward the spool axis.

The two core sections 16 . 18 essentially form one half of the core of the coil 10 in the connected state. On this core is the strand in the circumferential direction, ie, to the Coil axis wound around. The core will be at the ends of the coil 10 through flanges 20 . 22 limited. These flanges 20 . 22 are substantially parallel to each other and define axially a space for receiving the wound on the core strand. In essence, the flanges 20 . 22 formed by circular discs, which, however, in by radially outgoing from the coil axis ribs on the outer surface of the coil 10 are stiffened and can be provided with other facilities that are based on the purpose of the respective coil. Details of the flanges 20 . 22 will be described below.

Each of the core sections 16 . 18 has an approximately cylindrical shell 24 . 25 on. The coats 16 . 18 can also have a slightly conical shape to z. B. to facilitate stackability of the coil halves. The outer surface of the coats 24 . 25 forms the winding surface for the extruded material. The interior areas of the core sections 16 . 18 are shown in simplified form in the figures and can, for example, with reinforcements or means for receiving a shaft for rotation of the coil 10 be provided. For the sake of clarity, therefore, the figures show only the outer coats 24 . 25 the core sections 16 . 18 ,

Each of the coats 24 . 25 becomes the other core section 18 respectively. 16 through an outer joining edge 28 and an inner joining edge 26 limited. More precisely, the respective wall of the mantle 24 . 25 becomes the other core portion in the axial direction 18 respectively. 16 towards the inside of the jacket through the inner joining edge 26 and on the outside of the shell through the outer joining edge 28 limited. Each of these inner and outer joint edges 26 . 28 is intended to connect the two coil halves 12 . 14 on the respective corresponding inner or outer joint edge 26 . 28 the mantle of the opposite core section 18 . 16 to be set up.

Both the inner joining edge 26 as well as the outer joining edge 28 revolve around the respective core section 16 . 18 wave-shaped, each in the form of a sine wave. It thus arise in the course of the respective inner or outer joining edge 26 . 28 Wave mountains and wave troughs. The wave of the inner joining edge 26 is however opposite the shaft of the outer joining edge 28 phase-offset in the circumferential direction, namely a half-wave in a phase angle of 180 °, so that a wave crest of the outer half-wave in a phase angle of 180 °, so that a wave crest of the outer joining edge 28 on a trough of the inner joining edge 26 falls and vice versa.

This should be exemplified by the example in 1 lower core section 18 be explained in more detail. The in 1 upper edge of the coat 25 of the lower core section 18 has the inner joining edge extending in the form of a sine wave 26 and the radially outwardly adjacent outer joining edge 28 which also runs in the form of a sine wave, but opposite to the inner joining edge 26 is phase-shifted by one half-wave. As a result, along the direction of rotation, an alternating sequence is formed inwardly and outwardly stepped wall sections, wherein a wall section extends axially through a section of the outer joining edge 28 is limited and on its inside a gradation in the form of a portion of the inner joining edge 26 has, as inwardly stepped wall portion 32 to be designated, and a wall portion axially through a portion of the inner joining edge 26 is limited and on its outside a gradation in the form of a portion of the outer joining edge 28 has, correspondingly as stepped outward wall portion 30 , At the lower core section 18 become the inside stepped wall sections 32 by maxima of the outer joining edge 28 formed axially upward toward the upper core portion 16 projecting, wherein the inner gradations by minima of the inner joining edge 26 are formed, and the stepped-out wall sections 30 by maxima of the inner joining edge 26 formed, wherein the outer gradations by minima of the outer joining edge 28 be formed.

The formation of the connection area on the jacket 24 of in 1 upper core section 16 is identical, with an inner joining edge 26 and an outer joining edge 28 , whose course with the corresponding opposite joining edge 26 . 28 of the lower coat 25 is identical. According to the reverse orientation of the upper coil half 12 Here are the stepped outside wall sections 30 formed in the areas where the inner joint edge 26 axially downwards in the direction of the lower bobbin half 14 protrudes and thus, according to the orientation in 1 , a wave minimum, while the outer gradation at this wall portion 30 through the higher wave maximum of the outer joining edge 28 is formed. The same applies to the inwardly stepped wall section 32 at the upper core section 16 down through a wave minimum of the outer joining edge 28 is limited and its gradation on the inside of the jacket 24 by a wave maximum of the inner joining edge 26 is limited.

The two core sections 16 . 18 can be joined together such that an inwardly stepped wall section 32 a core section 16 . 18 with an outwardly stepped wall section 30 of the associated core section 18 respectively. 16 can overlap. In this overlapped state become the core sections 16 . 18 latched together by snap connections. These each comprise a projection in the present embodiment 34 , ie a raised area, on the stepped wall section 30 is provided, as well as a recess 36 in the form of an opening in the inwardly stepped wall section 32 whose shape is the lead 34 equivalent. Slides outwardly stepped wall section 30 behind the inside stepped wall section 32 That's how the lead becomes 34 from the recess 36 added. This is done by means of a rotary movement, as in the following in connection with the 2a - 2d should be described.

The 2a - 2d each are partial views of the juxtaposed core sections 16 . 18 , where the sequence of 2a - 2d a rotational movement of the upper core portion 16 on the lower core section 18 corresponds, in which the two connecting portions of the core sections 16 . 18 slide together and lock together. In 2a stand the stepped inside wall sections 32 the two coats 24 . 25 the core sections 16 . 18 exactly to each other, as well as the stepped outward wall sections 30 , The upper core section 16 thus lies with its deepest vertices, ie, the wave minimums of the inner and outer joint edges 26 . 28 on the corresponding upper vertices of the inner and outer joint edges 26 . 28 of the lower core section 18 on.

Will in this position, the upper core section 16 clockwise according to 1 turned, as in 2 B shown slide the inwardly stepped wall sections 32 of the upper core section 16 in the direction of the minima of the outer joining edge 28 of the lower core section 18 , wherein in each case an inwardly stepped wall section 32 of the upper core section 16 over an outwardly stepped wall section 30 of the lower core section 18 slides. At the same time an outwardly stepped wall section slides 30 of the upper core section 16 behind an interior stepped wall section 32 of the lower core section 18 , So that the projections 34 on the outwardly stepped wall sections 30 do not hinder this sliding movement, have the stepped outward wall sections 30 and / or the inwardly stepped wall sections 32 a certain elasticity to be able to yield to the inside or to the outside something. The projections 34 are about lens-shaped, as well as the corresponding recesses 36 ,

While 2c the rotational movement of the upper core section 16 opposite the lower core section 18 in a more advanced position shows 2d finally, the end position in which the inwardly stepped wall sections 32 and the stepped outward wall sections 30 completely overlap and the protrusions 34 in the recesses 36 are included. The outer joint edges 28 the two core sections 16 . 18 are completely on top of each other, just like the (in 2d hidden) inner joint edges 26 the two core sections 16 . 18 ,

It is understood that during the course of rotation in the 2a - 2d also a slight axial displacement of the two coil halves 12 . 14 must be in one another. A release of the two coil halves 12 . 14 from each other can take place by a rotation in the opposite direction with reverse movement. The release of the snap connections, ie, the engagement of the projections 34 in the recesses 36 can be facilitated by a slight finger pressure from the outside on the projections 34 is exercised in the recesses 36 exposed.

Due to the wave-shaped course, in particular the outer joining edge 28 is a pinching of the material between the core sections 16 . 18 almost impossible. The above-described connection of the core sections 16 . 18 along the undulating inner and outer joint edges 26 . 28 provides a positive guidance when connecting the coil halves 12 . 14 which simplifies the assembly, but at the same time a secure hold of the coil halves 12 . 14 guaranteed to each other in use.

3 and 4 show the coil 10 from two composite coil halves 12 . 14 in a side view in a perspective view. Details of the flanges 20 . 22 should be related to the 5 and 6 be explained in more detail.

As in the 5 and 6 can be seen in more detail, each flange has 20 . 22 an outer edge 40 on, which has a substantially arcuate or U-shaped cross-section. This cross section is in each case to the opposite coil half 14 respectively. 12 opened. 5 shows this outer edge 40 from above, that is from the side, that of the lower half of the coil 14 opposite and on which the outer edge 40 closed is. The open side of the outer edge 40 is in 6 to recognize.

The arcuate cross section of the outer edge 40 thus forms a vertical, ie, standing parallel to the coil axis outer wall 42 , which is comparatively thin and in a radial direction or impact against the outer edge 40 can give something away. This flexibility can be selected by choosing a suitable material for shaping the coil halves 12 . 14 favor, so for example by choosing a suitable plastic with elastic properties. Will the outer wall 42 pressed slightly inward, it does not break, but gives way and springs back on release of this pressure back to its original shape. Compared to conventional coils, this has the advantage that damage due to falls or blows can be largely avoided.

In 6 It can be seen that the arcuate cross section of the outer edge 40 on its inside by radial ribs 44 is slightly reinforced, which are circumferentially spaced from each other.

Within the outer edge 40 are other radial or star-shaped ribs 46 . 48 to reinforce the interior of the respective flange 20 . 22 arranged. As already mentioned, the respective flange 20 . 22 In particular, be provided on its outside with means for handling or identification of the coil, which should not be described separately, since they are not part of the present invention.

Claims (6)

Kitchen sink ( 10 ) for receiving wound-up extrudates consisting of two coil halves ( 12 . 14 ), of which each coil half ( 12 . 14 ) a core section ( 16 . 18 ) and the core sections ( 16 . 18 ) in the connected state, the core of the coil ( 10 ), characterized in that - each core section ( 16 . 18 ) an inner joining edge ( 26 ) and a radially adjacent thereto outer joint edge ( 28 ) for resting on a corresponding inner or outer joining edge ( 26 . 28 ) of the other core section ( 18 respectively. 16 ) comprising the core section ( 16 . 18 ) wave-shaped, - wherein the shaft of the inner joining edge ( 26 ) with respect to the shaft of the outer joining edge ( 28 ) is phase-shifted such that in the direction of rotation a sequence of inwardly and outwardly stepped wall sections (FIG. 30 . 32 ) is formed, each of which inwardly stepped wall section ( 32 ) of a core section ( 16 respectively. 18 ) in the connected state with an outwardly stepped wall portion ( 30 ) of the associated core section ( 18 respectively. 16 ) overlaps, and that the overlapping wall sections ( 30 . 32 ) are latched together by snap connections, each having a projection ( 34 ) located on one of the two overlapping wall sections ( 30 ) is provided, and a recess receiving the projection ( 36 ) in the other wall section ( 32 ). Coil according to claim 1, characterized in that the waves of the inner and outer joint edges ( 26 . 28 ) Are sine waves. Coil according to claim 1 or 2, characterized in that the projections ( 34 ) and recesses ( 36 ) are formed about lenticular. Coil according to one of the preceding claims, characterized in that each core section ( 16 . 18 ) an approximately cylindrical or conical jacket ( 24 . 25 ) whose wall is axially in the direction of the other core portion ( 16 . 18 ) on the inside of the jacket ( 24 . 25 ) through the inner joining edge ( 26 ) and on the outside of the jacket ( 24 . 25 ) through the outer joining edge ( 28 ) is limited. Coil according to one of the preceding claims, characterized in that each coil half ( 12 . 14 ) a flange ( 20 . 22 ) whose outer edge ( 40 ) has an arcuate cross-section. Coil according to claim 5, characterized in that the arcuate cross-section on its inside by radial ribs ( 44 ) is reinforced.

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