EP0920930A2 - Device for tilting wire windings after a coil forming head in a wire rolling line - Google Patents

Abstract

A slide plate to tilt the wire coils (1) is positioned behind the laying head (2) and in front of the laying rolling stage (3). The slide plate is bowl-shaped and pref. has a conical profile. The slide plate has a length of 100 - 500mm dependent upon rolling speed, and a radius larger than that of the wire coils. The slide plate has projecting side suspension studs, engaging into assembly pockets on the laying head.

Description

The invention relates to a device for tilting wire windings behind a winding layer in a wire mill, in particular in a high speed wire line.

In a wire mill, especially in a high speed wire mill, the wire turns into wire in a coiler shaped. The wire turns are then a cooling section serving conveyor belt. Behind the conveyor belt the coils become stackable and in a bundle forming station Transportable wire bundles collected and bound. Because of the high Wire speeds in a high speed wire line is a deflection of the wire at the end of the wire line from horizontal to vertically not possible. Therefore the turns are in one Coil layer "standing" formed and after leaving the coil layer folded into the horizontal position so that the wire turns lie horizontally fanned out on the conveyor belt and can be optimally cooled. Turning the wire turns on the conveyor belt is done in the prior art various simple, sometimes complex constructions that are sometimes burdened with considerable disadvantages.

From the German laid-open specification 28 37 912 is a device to fan out and deposit wire windings on a cooling section serving conveyor belt known. The device exists from a winding layer with the horizontal in one acute angle inclined axis of rotation and one in the direction of transport upwardly inclined first section of the conveyor belt. The first section of the conveyor belt is one in Storage area swiveling swivel axis distant in transport direction, the height of the fall of the turns emerging from the winding layer to change. The coater has a laying pipe, the slope of which is variable to the exit velocity of the exiting Turns and thus the characteristic of ballistic To change the laying curve. These measures are aimed at the Conveyor belt striking turns free of a braking Tilt the effect of the conveyor belt on the conveyor belt. Disadvantageous in this known device for fanning out and depositing the wire windings is the considerable constructive and technical control Effort with which the characteristic of the ballistic laying curve the wire turns are changed.

The object of the present invention is a simple and uncomplicated Device for tilting the wire turns behind the Coil laying device in a wire line, especially in a high-speed wire line to create which the wire turns gently and supportively folded. This device is intended in particular when tilting thin wire can be used because this thin, glowing wire sensitive to external forces e.g. Bumps responded.

This object is achieved in a device for tilting the wire windings of the type mentioned in the preamble of claim 1, that behind the winding layer and before the laying roller table a sliding plate is arranged for tilting the wire turns.

Further embodiments of the invention are in the subclaims described.

The sliding plate is preferably conical as a sliding shell Cross section formed. The length L of the sliding plate in the laying direction is variable and is between 100 mm and 500 mm. The The length of the sliding plate depends on the rolling speed. The turns must be braked when tipping, but they can do not come to a standstill.

In a further embodiment of the invention, it is proposed that that the sliding plate is not screwed to the winding layer, but only is suspended in two assembly pockets, which means a short assembly time is achieved.

In a further embodiment of the invention, the suspension point chosen for the sliding shell on the mounting hook so that the sliding shell is always pressed against the winding layer by its own weight.

In an embodiment of the invention it is further provided that the Radius of the sliding shell is larger than the radius of the winding, so that the Wire windings have some clearance on the side, but still from supported and slowed down below.

In a further embodiment of the invention it is provided that the sliding shell with respect to the center axis of the winding layer is inclined at an angle between 1 ° and 10 °. By the Use of different sliding shells with different angles α and with different length L is any desired mode of operation reached.

When changing programs, it becomes necessary or sensible is only replaced the sliding shell. All other components of the Wire mill, especially the winding layer and the cooling conveyor belt or the laying roller table do not need to be replaced or be redesigned.

Figur 1:

in Seitenansicht die Anordnung der Gleitschale zwischen Windungsleger und Legerollgang.

Figur 2:

Die Aufhängung der Gleitschale am Windungsleger in Seitenansicht und in

Figur 3:

in einer Ansicht von vorne.

The invention is described using an exemplary embodiment according to FIGS. 1 to 3. Show it:

Figure 1:

in side view the arrangement of the sliding shell between winding layer and laying roller table.

Figure 2:

The suspension of the sliding shell on the winding layer in side view and in

Figure 3:

in a front view.

The thin wire 1 rolled out in a high-speed wire line leaves the winding layer 2 at a horizontal speed, which is calculated from the product of the peripheral speed of the laying tube and the tangent of the exit angle according to the formula: V H = V U * tanα

E.g. the wire enters at 120 m / s peripheral speed with an exit angle of 2 ° with a horizontal speed of V H = 120 m / s * tan 2 ° = 4.2 m / s out of the winding layer 2. This horizontal speed is superimposed by the increasing vertical speed caused by the acceleration due to gravity, similar to a throwing parabola 4.

The wire windings meet the sliding plate 6 according to the invention, which is designed as a sliding shell. Due to the friction between Wire 1 and the sliding shell 6, the wire turns on the Bottom braked and tilted (see Fig. 1). The wire turns are fanned out onto the laying roller table 3 behind the sliding shell filed.

Figure 2 shows that the sliding shell 6 on the outside with protruding suspension pins 11 is provided, which is suspended in an assembly bag 5 are. The mounting pockets are molded into mounting brackets 12, which in turn are firmly connected to the winding layer 2.

FIG. 3 shows that the sliding shell 6 by means of a mounting rope 7 is held by a mounting hook 8, the mounting cable laterally protruding hinge pin 11 of the sliding shell 6. The center of gravity of the sliding shell 6 and its suspension is chosen so that the one end of the sliding shell is always on the end the protective hood 9 of the winding layer 2 is pressed, whereby any gap is avoided. The pressing torque or the pressing force the sliding shell 6 to the protective hood 9 is always larger than the frictional moment caused by the friction of the wire turns 1 arises on the sliding shell 6.

The radius R of the sliding shell 6 is preferably larger than that Radius of the wire turns 1 executed so that the turns laterally have some free space and not through the walls of the sliding shell 6 are squeezed or reshaped or damaged.

By using different sliding shells 6 with different Cone angle α and different length L will be any desired Operating mode reached (see Fig. 2).

When changing programs, it becomes necessary or sensible is, only the sliding shell 6 replaced.

Claims (11)

Device for tipping wire windings behind a winding layer (2) in a wire mill, in particular in a high-speed wire mill,
characterized,
that a sliding plate (6) for tilting the wire windings (1) is arranged behind the winding layer (2) and before the laying roller table (3). Device according to claim 1,
characterized,
that the sliding plate (6) is designed as a sliding shell, preferably with a conical cross section. Device according to claim 1 or 2,
characterized,
that the length (L) of the sliding shell (6) has a length of 100 to 500 mm depending on the rolling speed. Device according to claim 1, 2 or 3,
characterized,
that the radius of the sliding shell (6) is larger than the radius of the wire turns (1). Device according to at least one of claims 1 to 4,
characterized,
that the sliding shell (6) is hooked onto the winding layer (2) in at least two mounting pockets (5). Device according to at least one of claims 1 to 5,
characterized,
that the sliding shell (6) is provided with laterally projecting hinge pins (11) which engage in the mounting pockets (5). Device according to at least one of claims 1 to 6,
characterized,
that at least one locking washer (10) is arranged on each of the hinge pins (11), with which the slipping of an assembly cable (7) is prevented. Device according to at least one of claims 1 to 7,
characterized,
that the mounting rope (7) is held on a mounting hook (8). Device according to at least one of claims 1 to 8,
characterized,
that the suspension point of the sliding shell (6) on the mounting hook (8) is selected so that the sliding shell (6) is pressed against the winding layer (2) by its own weight. Device according to at least one of claims 1 to 9,
characterized,
that the cone angle (α) of the sliding shell (6) is between 1 ° and 10 °. Device according to at least one of claims 1 to 10,
characterized,
that the axis of the sliding shell (6) with respect to the central axis x - x of the winding layer (2) is inclined at an angle (α) of 1 ° to 10 ° downwards towards the laying roller table (3).

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