EP1507607A1

EP1507607A1 - Metal extrusion press, in particular a horizontal metal extrusion press

Info

Publication number: EP1507607A1
Application number: EP03737894A
Authority: EP
Inventors: Karl Hermann Claasen; Uwe Muschalik
Original assignee: SMS Eumuco GmbH
Current assignee: SMS Group GmbH
Priority date: 2002-05-24
Filing date: 2003-05-15
Publication date: 2005-02-23
Also published as: JP2005524538A; DE10393088D2; US20050188863A1; AU2003245834A1; DE10222951A1; WO2003099481A1

Abstract

The invention relates to a metal extrusion press (1), in particular a horizontal metal extrusion press (1), comprising a charging device (7) for charging an ingot to be extruded (6) into an ingot receptacle. According to the invention, the charging device (7) brings an ingot (6) that is received in a charging position and held in a charging tray (18) into the centre or the axis (8) of the extrusion press in order to insert it into the ingot receptacle. The charging device (7) of said metal extrusion press comprises an ingot insertion unit (28) which contains two intercoupled motion-dependent sliding cylinders (29a, 29b). Said cylinders (29a, 29b) are fixed by their piston-rod heads (31a, 31b) to a linear guided insertion finger (25) and their cylinder bases are likewise pivotally mounted in bearing rings (30a, 30b).

Description

Metal extrusion press, especially horizontal metal extrusion press

The invention relates to a metal extrusion press, in particular a lying metal extrusion press, with a loading device for loading a block to be pressed into a block receiver, for which purpose the loading device moves a block received from a loading position and held in a loading tray into the press center or axis for insertion into the block receiver ,

Such an extrusion press with a loading device in the form of a swivel loader, as is customary as an alternative to linear loaders, has become known from EP 0 791 413 B1. The swivel arm that has the charging cradle or a comparable loading device such as a pair of pliers or rifle is moved from a loading position into an intermediate position and further into the press axis. In order to exclude disruptions in the workflow, an exact approach to the positions by the charging cradle or the like is required. In order to achieve this with the shortest possible idle times in the press cycle, in particular for loading a block, the swivel arm is dimensioned for the swivel angle between the intermediate position and the press axis and is designed as a satellite swivel part. A basic swivel part is assigned to this satellite swivel arm for the swivel path between the loading position and the intermediate position, the satellite swivel arm being staggered in time or movable at the same time relative to the base swivel part. The satellite swivel arm guided in the base swivel part is moved in the base swivel part via a pinion driven by a motor and gear. The block positioned in the middle of the press is inserted into the block receiver of the extrusion press using a slide. The slider serving for the block feed must be brought into position or retracted separately when the swivel loader is in the intermediate position.

From EP 0 428 989 A2 a block loader with fork-shaped charging shells is known, one of which is provided on a swivel arm, the two swivel arms being arranged in a rotationally fixed manner on a shaft are, a swivel arm but is axially displaceable on the shaft by means of a piston-cylinder unit. A block heated to the pressing temperature in an oven is taken over by the charging cradles and brought into the free space between the die and the press disk by pivoting the swivel arms into the press axis. By means of an adjusting cylinder, the machine beam with the block receiver is moved towards the die, the block receiver being put over the block. In accordance with the advance of the block pickup, the axially movable swivel arm is shifted on the shaft until the block is clamped between the press ram and the counter beam or their die fastened in a holder. The swivel arms with the charging cradles can then be swung out for a new loading process. This loading process requires the use of the press ram.

The invention has for its object to provide a swivel loader in a generic extruder that can be used more variably and is independent of the press ram for the loading process.

This object is achieved in that a block insert having two movement-dependent coupled push-in cylinders is arranged on the loading device, the push-in cylinders with their piston rod heads being pivotally fastened to a linear positively guided push-in finger and their cylinder bottoms also pivotably mounted. The two push-in cylinders integrated in the loading device, preferably arranged in a common support frame fastened to the loading device, enable a lever mechanism with their connection to the push-in finger with a pendulum-like movement around the articulation points on the cylinder bottom when the push-in finger moves back and forth. Here, with the positively guided linear displacement of the insertion finger and the accompanying pushing of the block into the block receiver, there is at the same time a temporary spatial displacement of the push-in cylinders arranged in a V-shape from the insertion finger in the supporting frame. Because while the push-in cylinder, which is removed from the block receiver in the starting position, changes in the forward movement of the insertion finger with an increasing number of piston rods coming out of the cylinder into an inclined position aligned with the block receiver around the base-side articulation or fastening point, the other cylinder leads exactly opposite movement and shift through. Its cylinder base, which is aligned in the initial position in an inclined position on the insertion finger and fastened there with its extended piston rod, pivots about the base-side articulation or fastening point and a correspondingly shortening piston rod into an upright position. This is achieved when the insertion process has ended and the insertion finger is in front of the block sensor. This interplay is repeated with each reset of the insertion finger to its starting position and with each new loading process. To push the block into the block receiver, it is not necessary to move the barrel of the press and the press ram. According to the invention, all of this is carried out by the push-in cylinder unit in cooperation with the insertion finger, this unit being immediately brought into position in front of the block receiver by the loading device both in a swivel loader and in a linear loader, so to speak as a backpack.

An embodiment of the invention provides that the charging cradle is pivotally hinged to the push-in cylinder support frame. In the loading position, the charging cradle can be pivoted about its articulation point in order to take over and hold the metal block conveyed by an oven and heated to the pressing temperature in such a way that it surrounds the block over a sufficiently large extent. In the same way, it can be folded down in a simple manner after the block has been inserted into the block receiver, so that the block can be pressed out immediately.

According to one embodiment of the invention, the piston rods act on the charging cradle from adjusting cylinders articulated on the bottom of the charging device. For block loading, there is therefore a compact structural unit which has all the necessary movement elements, and in particular also is suitable for retrofitting conventional block loaders. This creates a prerequisite that larger block lengths can be processed on the extrusion press.

According to one embodiment of the invention, the charging cradle has a plurality of strips arranged at the same angular distance from one another. It is recommended that the inner surfaces of the strips facing the block are equipped with rollers. The rollers promote the low-friction transfer of the block from the charging cradle to the block receiver. The distribution of the strips ensures that the block is securely enclosed at several points in a line.

If a bar equipped with rollers is advantageously provided on the push-in cylinder support frame for the bars of the charging cradle, the area surrounding the circumference of the block can be enlarged.

According to a further design feature, a loading device designed as a swivel loader can advantageously be acted upon by swivel cylinders arranged below the press frame transversely to the center of the press. These adjust the push-in cylinder support frame provided laterally in the longitudinal direction next to the extrusion press from the loading position into the center of the press, for which purpose the swivel loader is mounted on a rigid swivel axis.

Further features and details of the invention result from the claims and the following description of an embodiment of the invention shown in the drawings for an extruder with a swivel loader as a loading device. Show it:

1 is a partial cross-section of an extrusion press with a view of its die holder arranged in a counter beam and a swivel loader shown laterally in its block transfer or loading position in the extrusion direction; and

Fig. 2 as a detail of the swivel loader in section along the line II-II of Fig. 1st Of a well-known metal extrusion press 1, only one counterbeam 5 is provided in FIG. 1, provided with a die holder, as indicated only by the reference number 2, arranged in the press frame 3 and connected to a cylinder spar, which is at the front in the plane of the drawing and is not shown, via armature 4 shown. Arranged on the press frame 3 is a block receiver holder which is provided with a block receiver and is moved towards the die holder 2 in order to press a block. The spar, not shown, carries a press ram which presses the block inserted into the block receiver through the die of the die holder 2.

To load a block 6 into the block receiver, the metal extrusion press 1 according to the exemplary embodiment is equipped with a swivel loader 7, which can be loaded from below the press frame 3 transversely to the press center or axis 8 in a crossmember 9 and is pivotable about a rotation axis 11. The pivot cylinders 10 are provided with their piston rods 12 movably via a pivot point 13 with the swivel loader 7 and movably via a pivot point 14 on the cylinder bottom in the crossmember 9.

The swivel loader 7 is formed on its free end projecting laterally from the press frame 3 in the manner of a hammer head 15, to which a support frame 16 (see FIG. 2) is attached, which holds the hammer head 15 of the swivel loader 7 in the position shown in FIG. 1 loading position "B" clearly protrudes upwards. On the one hand on the hammer head 15 and on the other hand on a crescent-type charging cradle 18 which is pivotably arranged on a pivot axis 17 of the supporting frame 16, adjusting cylinders 19 are movably mounted via their piston rods and cylinder bottoms.

The lower end of the support frame 16 lies with an attenuator 20 on a support 22 attached to the foundation 21. At the upper end of the support frame 16, which is removed from the floor or foundation 21, a strip 24 equipped with rollers 23 on its free surface is arranged in a stationary manner. This also acts in the charging cradle 18 at the same angular distance α from one another strips 24 equipped with rolls 23 together in order to enclose the block 6 over the largest possible extent and to be able to hold it securely in spite of its free, ie not clamped, support. At the upper end of the support frame 16, an insertion finger 25 is further arranged with the interposition of a guide block 26. The block 6 is fed to the charging cradle 18 in the loading position "B" via an upstream feed 27.

The insertion finger 25 with the guide block 26 is part of a block insert 28, shown in more detail in FIG. 2, arranged in the support frame 16. This further comprises two push-in cylinders 29a, 29b, which are pivotally fastened at the bottom in the support frame 16 with bearing eyes 30a, 30b on the cylinder bottom and with their piston rod heads 31a, 31b are articulated on the guide block 26 of the insertion finger 25. In FIG. 2, the support frame 16 with its block insert 28 is assigned to the left on the outside a block receiver 32 of the extrusion press, into which the block 6 is inserted before it is subsequently pressed through the die of the die holder 2 (cf. Fig. 1) is pressed.

To push the block 6 into the block receiver 32, the guide block 26 with the insertion finger 25 is moved linearly in the direction of the arrow, the block 6 being conveyed into the block receiver 32 with little friction due to its support on the rollers 23 of the strips 24 of the charging cradle 18. In this case, the push-in cylinders 29a and 29b, which are arranged in a V-shape in the starting position from the guide block 26, shift with the opposite movement of their piston rods 34a, 34b, i.e. the piston rod 34b emerges from the cylinder, while likewise the piston rod 34a shortens, into the insertion end position indicated in FIG. 2 for the identical components by a prime symbol.

The positive guidance of the movement sequences is favored here if the push-in cylinders 29a, 29b are guided in the manner of a sliding block with bolts 35 in predetermined raceways 36. After the block 6 is pushed into the block receiver 32, the block inserter 28 is reversed and with opposite movements and spatial displacements of the push-in cylinders 29a, 29b are moved back to the starting position shown on the right in FIG. 2, in which the insertion finger 25 is in front of the charging cradle 18.

The pivoting of the swivel loader 17 together with the supporting frame 16 with the block 6 accommodated in its loading cradle 18 into the push-in position in which the block 6 is in alignment with the die holder 2 and the block receiver 32 (as indicated in FIG. 2) is shown in FIG 1 shown. The identical reference numerals provided with a prime also again illustrate the different positions of the associated components, the reference numerals without the prime corresponding to the starting position. Accordingly, when the swivel cylinders 10 are acted upon, the swivel loader 7, with its support frame 16 having the block slide-on device 28, moves from the loading position "B" to the squeezing position "A", in which the block 6 is located in the press center 8 in the manner described above , During the pivoting, the swivel loader 7 covers a defined movement about the axis of rotation 11. After the block 6 has been pushed into the block receiver 32 (FIG. 2), the charging cradle 18 'is swung downward about the pivot axis 17', so that even while the pivoting loader 7 'is being pivoted back into its starting position for the loading position "B", the barrel spar also the press ram (not shown) for pressing the block 6 in the direction of the die holder 2 can be moved.

Claims

claims:

1. Metal extrusion press, in particular lying metal extrusion press, with a loading device for loading a block to be pressed into a block receiver, for which purpose the loading device moves a block received from a loading position and held in a loading tray into the press center or axis for insertion into the block receiver, thereby characterized in that a block insert (28) having two movement-dependent coupled push-in cylinders (29a, 29b) is arranged on the loading device (7), the push-in cylinders with their piston rod heads (31a, 31b) on a linear positively guided push-in finger (25) are attached and their cylinder bottoms in bearing eyes (30a, 30b) are also pivotally mounted.

2. Metal extrusion press according to claim 1, characterized in that the push-in cylinders (29a, 29b) are arranged in a common support frame (16).

3. Metal extrusion press according to claim 1 or 2, characterized in that the push-in cylinder (29a, 29b) starting from the insertion finger (25) are arranged in a V-shape.

4. Metal extrusion press according to one of claims 1 to 3, characterized in that the charging cradle (18) is pivotally articulated on the support frame (16).

5. Metal extrusion press according to one of claims 1 to 4, characterized in that the piston rods act on the charging cradle (18) from the bottom on the loading device (7) articulated adjusting cylinders (19).

6. Metal extrusion press according to one of claims 1 to 5, characterized in that the charging cradle (18) has a plurality of strips (24) arranged at the same angular distance (α) from one another.

7. Metal extrusion press according to claim 6, characterized in that the block (6) facing inner surfaces of the strips (24) are equipped with rollers (23).

8. Metal extrusion press according to one of claims 1 to 7, designed with a swivel loader as a loading device, characterized in that the swivel loader (7) from below the press frame (3) transversely to

Press center (8) arranged pivot cylinders (10) can be acted upon.