EP1134049A1 - Filling chamber for horizontal thixoforming devices - Google Patents

Abstract

Filling chamber has a bearing element (20) with an upper side (21) lying on a filling vessel (13) for placing a pre-heated thixotropic metal bolt (10) so that the metal bolt can be roll or pushed with a controlled movement from the bearing element though a longitudinal opening (16) into the filling vessel. An Independent claim is also included for a process for transferring a pre-heated thixotropic metal bolt into the filling chamber of a horizontal thixoforming device. Preferred Features: The longitudinal opening is limited by longitudinal edges (17) and the bearing element lies on the filling vessel along a longitudinal edge.

Description

The present invention relates to a filling chamber of a horizontal thixoforming system Inclusion of a preheated thixotropic metal bolt, the filling chamber one Filling chamber cavity and a filling device with a filling vessel for insertion contains the thixotropic metal bolt in the filling chamber and the filling vessel a cylindrical one Hollow body with an elongated cavity and one along a longitudinal axis of the filling chamber (x) extending longitudinal opening for inserting the metal bolt transversely to the longitudinal axis of the filling chamber (x) in the filling vessel, and a method for inserting metal bolts in the thixotropic state in a filling chamber according to the invention.

Thixoforming concerns the production of molded parts from metal bolts with thixotropic Characteristics. The forming is usually done specifically for this thixoform process developed thixoforming systems, which are also referred to as die casting systems because the Thixo forming process is closely related to a die casting process.

The above-mentioned horizontal thixoforming plant for producing thixiform parts usually contains in addition to the filling chamber, a mold cavity adjoining the filling chamber and a piston for pressing the metal bolt out of the filling chamber into the Mold cavity.

With thixoforming, the thixotropic properties of partially liquid or partially solid metal alloys exploited. The thixotropic properties of a metal alloy mean that a suitably prepared metal behaves unloaded like a solid, under Pressure and shear stress reduces its viscosity to such an extent that it looks similar a molten metal behaves. This involves heating the alloy into the solidification interval between liquidus and solidus temperature required. The temperature is like this adjust that, for example, a microstructure content of 20 to 80 wt .-% melted the rest remains in solid form.

The metal bolt is heated, for example, in a specially developed one Resistance or induction furnace. The metal bolt is used after heating Transport device, in particular by means of a transport container, to the, usually horizontally arranged, Filling chamber of the thixoform plant transported and transferred to the filling chamber. By pressurizing a piston, the metal bolt is removed from the Filling chamber injected or pressed into the mold cavity via the sprue, in which presses the thixotropic metal alloy into the desired shape and solidifies brought.

The cavity of the filling chamber which receives the metal bolt is generally of the cylindrical shape adapted to the metal bolt. The filling chamber usually has a filling device on, in the form of a cylindrical hollow body with a longitudinal axis in the direction of the filling chamber running filler opening is formed through which the metal bolt is transferred from above into the cavity.

The metal bolts are transported from the heating furnace to the filling chamber by means of a transport device. The transport device usually consists of a robot-controlled Gripping arm, which holds the metal bolt in an open transport container to the filling chamber promoted. The metal bolt is made by tilting the transport container, which is open in the longitudinal direction over the filling opening of the filling device provided in the filling chamber transferred.

On the one hand, the transport container with the metal bolt tipped outside the filling chamber must be and on the other hand the gripping arm or the transport container from technical For this reason, the filling opening of the filling chamber cannot be fully moved up to can, the metal bolt is usually dropped into the filling chamber. The metal bolt is usually around 15 to 20 cm in free fall during the transfer dropped the fill opening into the fill chamber.

The shock of this case, however, causes deformations and inhomogeneities on or in Metal bolt. These property changes have an extremely negative effect on the thixoforming process and thus the quality of the finished molded part.

The object of the present invention is a filling chamber of a horizontal thixoforming system a filling device, which controls the controlled transfer of a metal bolt from a Transport device, in particular from a transport container, into the filling chamber allowed, the metal bolt during its transfer no shock-like, negative accelerations should experience.

According to the invention, this is achieved in that a support element with an upper side for placing a preheated thixotropic metal bolt on the filling vessel or is attached to this, so that a metal bolt in controlled movement from Support element can be rolled or pushed through the longitudinal opening into the filling container can.

The longitudinal axis of the filling chamber (x) corresponds to the concentric central axis of the filling chamber.

The support element is preferably arranged in such a way that its upper side is joined with a Horizontal plane (H) an angle α of greater than 0 °, preferably greater than 5 °, in particular greater than 15 °, based on a full circle of 360 °. Further is said angle suitably less than 60 °, preferably less than 45 °, in particular less than 35 ° and advantageously less than 25 °.

In a further embodiment of the invention, the top of the support element closes with a Horizontal plane (H) an angle α of greater than -20 °, preferably greater than -10 °, in particular greater than -5 °, based on a full circle of 360 °. The negative angles mean that the above-mentioned side is positive towards the filling vessel Has slope.

The top of the support element can have a horizontal plane (H) in a further embodiment the invention also an acute angle α of greater than -5 °, preferably the same or larger than 0 ° and smaller than 15 °, preferably smaller than 10 °, in particular smaller include as 5 °, based on a full circle of 360 °.

The positive slope of the top towards the filling vessel can serve, for example, the metal bolt when it is transferred from the transport device into the filling chamber to brake and bring it to a lower displacement speed so that the Metal bolt slides or rolls into the filling chamber as gently as possible.

The top side receiving the metal bolt is preferably flat. It can be changed Execution of the invention also have a shape deviating from flatness and, for example with a surface pattern, e.g. Roughness pattern, be structured or have a topography and e.g. be arched. The top can e.g. partially or be completely convex or concave. If the top has a topography, so should be related to the aforementioned and related to a horizontal plane (H) Angle information instead of the top side, a plane centering the topography is used become.

The support element is preferably plate-shaped and designed as a so-called support plate. The support element can be made of a high-melting metal or ceramic or be a combination of both materials. The support element is preferably made of a composite material, the composite material having a lower, the underside, Contains partial plate made of a high-melting metal and this lower partial plate an upper, top-containing, partial plate made of a heat-insulating, ceramic Material rests. The support element can also be heated.

The refractory metal can be copper or a copper alloy. More melting Metals can be ferrous or carbon-containing metals, preferably steel, in particular tool, hot work or stainless steel.

The ceramic material can contain or consist of an Al ₂ O ₃ , Al ₃ O ₄ , BN, SiC, Si ₃ N ₄ , MgO, TiO or ZrO ₂ .

The longitudinal opening of the filling container is preferably delimited by longitudinal edges. The In an embodiment of the invention, the support element lies against the longitudinal edge or is more preferred Flanged version along the longitudinal edge.

The support element can be made using known connection techniques, such as welding, riveting, Screwing, gluing, clamping or combinations thereof, to the longitudinal edge of the longitudinal opening be fastened in the filling vessel. The support element can be in an embodiment of the invention as separate, e.g. movable, be designed and device when the Place the metal bolt in the filling chamber on the filling vessel.

The expansion of the support element in the direction of the longitudinal axis of the filling chamber of the filling vessel can be shorter, the same length or longer than the length of the metal bolt. Is preferred the support element is the same length or longer than the metal bolt. The extension of the support element transversely to the longitudinal axis of the filling chamber can, for example, be of the order of magnitude half to full diameter of the metal bolt. The expansion can also be more than the diameter of the metal bolt.

In a special embodiment of the invention, in particular with small or negative peaks Angles α between the top of the support element and a horizontal plane (H), the filling device can be guided horizontally on the top of the support element Tappet included, which the metal bolt placed on the support element in the Filling cup pushes or pushes the metal bolt and in a rolling movement in the direction of the filling vessel. The ram is, for example, by means of hydraulic drive and moved back.

In a further embodiment of the invention, the support element can be an integral part of the filling container. This means that the filling vessel forms on one of its longitudinal edges the longitudinal opening, for example as described above, from support element.

The metal bolts are preferably cylindrical, in particular circular cylindrical. The Metal bolts can, for example, also be oval in cross section. The shape of the metal bolt should enable the metal bolt to roll if possible. The metal bolts have for example a maximum diameter of 50 to 180 mm, in particular from 80 to 150 mm. Their length is, for example, 80 to 500 mm.

The filling device can be used as a separate unit connected to the filling chamber or as integral device unit of the filling chamber. In a preferred version the filling device and in particular the filling vessel is an integral part of the filling chamber.

The cavity of the filling vessel is in cross section along the longitudinal axis of the filling chamber consistently formed and expediently describes a partial circle or a partial oval and has adjoining, mutually parallel walls or contains adjoining walls that are at an acute angle to each other so that the Cavity expanded from the inside out. The specified circle or oval preferably closes a central angle of 120 ° to 180 °, based on a full circle of 360 °, a.

The cavity of the filling vessel preferably has a U-shaped to semicircular shape Cross section on. The cross-sectional diameter of the cylindrical cavity the filling vessel is expediently the same and preferably slightly larger than the bolt diameter.

The cavity is preferably such that the metal bolt has a central angle of at least 45 ° and at most 180 °, in particular from 90 ° to 120 °, based on a full circle of 360 °, including part of the cylinder surface form-fitting inner wall of the filler vessel is in contact, so that the soft metal bolt without deforming stored in the filling chamber and shifted in the direction of the longitudinal axis of the filling chamber can be.

Furthermore, the cavity wall of the filling vessel adjacent to the support element closes in preferred embodiment with a horizontal plane H an angle β of less than 90 °, preferably less than 70 °, especially less than 50 ° and more than 5 °, preferably of more than 15 °, in particular of more than 30 °, so that the over Support element rolling metal bolts into the filling vessel without falling over the cavity wall rolls into the cavity.

In cross-sectional view, the cavity is preferably mirror-symmetrical, with one leading through the longitudinal opening and the longitudinal axis of the filling chamber (x) Filling chamber longitudinal axis (x) and dividing the cavity into two equal halves Directional plane (E) as a plane of symmetry.

The filling vessel can be thermally insulated and / or heated. The wall of the filling container suitably consists of a high-melting metal or ceramic or one Combination of both materials.

The wall preferably consists of a composite material, the composite material has an outer wall made of a high-melting metal and this outer Wall accommodates an inner wall made of a heat-insulating ceramic material. In a preferred embodiment, one or more of the above-mentioned high-melting Metals and one or more of the above-mentioned ceramic materials used.

With the aforementioned design of the filling vessel, the heat is extracted from the metal bolt reduced and the metal solidifies less quickly. The filling chamber is also possible to be provided with heating devices. These heaters can, for example, as Heating rods or as holes in which a heated medium such as Oil circulates in be arranged the wall of the filling chamber.

The length of the longitudinal opening of the filling device is the same and preferably greater than that Bolt length, in particular 30 to 80 mm larger than the bolt length. It preferably corresponds the length of the support element.

In a special embodiment of the invention, the longitudinal opening is arranged such that the leading through the longitudinal opening and the filling chamber longitudinal axis and the cavity in directional plane (E) dividing two equal halves is inclined and with a horizontal plane (H) an acute angle β of 5 ° to 90 °, preferably 10 ° to 60 °, and in particular from 15 ° to 50 °, based on a full circle of 360 °. At an acute angle of less than 90 °, the opening is thus inclined to the side, with a sharp one Angles of less than 5 ° gradually lay the opening in a horizontal orientation is coming.

In the case of an inclined direction plane (E), the support element is expediently on the lower one Longitudinal edge of the longitudinal opening provided.

It can also be provided that the filling vessel for the purpose of receiving a metal bolt is rotatable about the filling chamber axis, so that the directional plane (E) e.g. from one vertical alignment with an angle β of 90 ° to the horizontal plane (H) in an inclined, lateral alignment can be performed with an angle of less than 90 °, i.e. the filling vessel with the longitudinal opening is used to hold the metal bolt sideways rotated so that the slope of the cavity wall facing the support element Filling vessel is reduced and the metal bolt controls over the cavity wall mentioned can roll into the filling container.

The invention further comprises a further preferred embodiment, which is thereby is distinguished by the fact that the filling vessel consists of a movable one transverse to the longitudinal axis (x) of the filling chamber there is a first wall segment and a second wall segment, and the first wall segment on one at a junction between the first and second Wall segment attached at the end or adjacent and leading away from the filling vessel Support element is slidably positioned relative to the second wall segment and that first wall segment in a relative inner, closed end position with the second Wall segment forms a cylindrical cavity and the filling vessel in one relative longitudinal open end position of the first wall segment forms a longitudinal opening, so that a metal bolt in controlled movement from the support element can be rolled or pushed through the longitudinal opening into the filling vessel.

The filling vessel forms in an inner, closed end position of the first wall segment preferably a cylindrical cavity with a longitudinal axis along a filling chamber (x) extending longitudinal opening with longitudinal edges. By the shift the first wall segment on the support element in an outer open end position, the longitudinal opening is expanded in cross-section to the top of the support element.

The first and second wall segments can be in the inner, closed end position of the first wall segment also a cross-sectionally closed, cylindrical cavity form, in this embodiment the longitudinal edges of the filling vessel a line of contact form between the first and second wall segments. By the shift of the first wall segment on the support element in an outer open End position, a longitudinal opening is established at the top of the support element.

The connection point dividing the filling vessel into a first and second wall segment is useful between an upper longitudinal edge of the filling vessel and the lowest point of the cavity and preferably arranged at the lowest point of the cavity.

The support element is preferably with the lowest point of its top on the Height of the low point of the cavity arranged at the junction.

The first wall segment preferably closes a central angle of 90 ° to 120 °, referred to to a full circle of 360 °. The wall segment is, for example, by means of a hydraulic drive postponed.

The filling vessel of this variant, in particular its cavity, can be one of the have numerous previously described geometric shapes. The nature and the structure of the filling vessel can also be one of those described above Embodiments correspond. Other features described above the filling device are also on the aforementioned filling device with segmented Filling cup applicable.

Analogously to the filling vessel, the filling chamber can also be designed to be heat-insulating and / or be heated. The filling chamber can in particular use the same structure have the same, above-mentioned, materials as the filling vessel.

The invention also relates to a method for transferring a preheated thixotropic Metal bolt from a transport device into the filling chamber of a horizontal thixoforming system via a filling device.

The method is characterized in that the metal bolt by means of a transport device oriented in the direction of the longitudinal axis of the filling chamber (x) on top of one on the filling vessel adjacent or attached support element is deposited and the metal bolt over the support element transversely to the longitudinal axis of the filling chamber (x), if necessary by means of Kicked off by a pestle, a wall segment or the transport device in controlled guided movement rolled or pushed into the filling vessel through a longitudinal opening is and a piston the metal bolt from the filling vessel into a filling chamber cavity pushes the filling chamber.

In a preferred embodiment of the method, the top of the support element also closes a horizontal plane (H) an acute angle of greater than 0 ° and points in the direction Filler vessel on a negative slope, so that the metal bolt after it is in place following the support element with or without the impact of gravity into the filling vessel rolls.

In a further embodiment of the method, the metal bolt is transported using a transport container Filling device transported. The transport container is immediately on or immediately tilted over the support element so that the metal bolt comes out of the transport container the top of the support element rolls and follows gravity and if necessary by pushing through the transport container or using a plunger over the support element rolls into the filling vessel.

In another embodiment of the method, the filling vessel consists of a transverse to the filling axis longitudinal axis movable, first wall segment and a second wall segment. The first wall segment is on one at the junction between the first and the second wall segment end-mounted support element slidably positioned. The connection point separates the filling vessel between an upper longitudinal edge Filling vessel and the cavity low point, preferably at the cavity low point, in one first and second wall segment. The first wall segment is used to insert the metal bolt led to an outer end position on the support element. The metal bolt is placed on the support element between the first and second wall segments.

The first wall segment is then countered over the top of the support element pushed the metal bolt. The first wall segment then pushes the metal bolt in the filling vessel and is moved into an inner, closed end position, in which the first and second wall segments form a U-shaped to circular cavity.

Thanks to the device according to the invention and the method according to the invention for Inserting the metal bolt into the filling chamber can cause the impact when reloading as well Larger blows, especially the shock of falling into the filling container due to high Avoid negative accelerations of the metal bolt on impact in the filling container become. Deformation of the metal bolt as well as adverse changes in the inner The structure of the metal bolt can be prevented in this way. The metal bolt maintains its homogeneity and its ideal geometric shape.

Furthermore, thanks to the filling chamber according to the invention, the bolt needs to be avoided from being pushed as close as possible to the filling chamber by bumps during reloading. Rather, the design of the support element itself can determine with which distance tolerances a metal bolt, e.g. by means of a swivel arm to the filling chamber should be brought up.

Fig. 1a-c:

einen schematischen Querschnitt durch eine erfindungsgemässe Einfüllvorrichtung während des Einbringens des Metallbolzens in das Einfüllgefäss;

Fig. 2a-b:

einen schematischen Querschnitt durch eine erfindungsgemässe Einfüllvorrichtung mit einem Einfüllgefäss bestehend aus zwei Wandsegmenten;

Fig. 3:

einen schematischen Querschnitt durch eine Horizontal-Thixoformanlage mit erfindungsgemässer Einfüllvorrichtung.

The invention is explained in more detail below by way of example and with reference to the accompanying drawings. Show it:

1a-c:

a schematic cross section through a filling device according to the invention during the introduction of the metal bolt into the filling vessel;

2a-b:

a schematic cross section through a filling device according to the invention with a filling vessel consisting of two wall segments;

Fig. 3:

a schematic cross section through a horizontal thixoforming system with filling device according to the invention.

1 shows a first embodiment variant of a filling device 12 according to the invention and the process sequence for introducing a metal bolt 10 into the filling vessel 13. The filling device 12 contains a filling vessel 13 with an inner wall 23 a ceramic material and an outer wall 24 made of a high-melting Metal (Fig. La-c). The filling vessel 13 has one against the longitudinal opening 16 expanding U-shaped cavity 14. The longitudinal opening 16 is oriented slightly laterally, so that the directional plane E (Fig. 1c) to a horizontal plane H in an acute Angle β is from around 40 ° to 50 °. At the lower longitudinal edge 17 of the longitudinal opening 16 is a support plate 20 with a bottom 22 and a top 21 flanged. The Platen 20 is at an acute angle α of around 1 ° to 10 ° to a horizontal plane H and has a negative slope towards the longitudinal edge 17.

A preheated, thixotropic metal bolt 10 is in a transport container 30 to the Support plate 20 guided and tilted laterally, so that the metal bolt 10 laterally from the Transport container 30 rolls on the top 21 of the support plate 20 (Fig. 1a-b). Through the Inclination of the support plate 20, the metal bolt 10 rolls into the Cavity 14 of the filling vessel 13 (Fig. 1b-c). Since the direction plane E is inclined, the metal bolt 10 roll into the filling vessel 13 without falling along the cavity wall.

The metal bolt 10 is then removed from the filling vessel 13 by means of pressure piston 46 injected or pressed into the filling chamber cavity 42 and from there into the mold cavity 54 (see also Fig. 3).

The direction plane E or the longitudinal opening 16 can change the present embodiment also be aligned vertically, the 10 for filling the metal bolt Filling vessel 13 is rotated in the longitudinal axis x. Furthermore, the platen 20 of the described filling device 12 may be aligned horizontally or even a positive Have slope in the direction of the filling vessel 13.

A further embodiment variant of the present invention is represented by FIGS. 2a-b. The filling vessel 13 'consists of a first wall segment 25 made of a ceramic Material and a second wall segment 26, containing an outer wall 24 ' made of a high-melting metal and an inner wall 23 'made of a ceramic Material.

At the junction 27 between the first and second wall segments 25, 26 the extended end of a support plate 20 'inserted. The top 21 'of the platen 20 'lies at the level of the lower cavity apex, i.e. at the bottom of the cavity 19 in the filling vessel 13 '.

The first wall segment 25 comprises a central angle of approximately 120 °, based on one Full circle of 360 °. The first wall segment 25 is slidable on the top 21 'of the Platen 20 'positioned. The support plate 20 'is aligned horizontally. she can however, also have a negative or positive slope toward the filling vessel 13 '.

The first wall segment 25 is used to insert the metal bolt 10 into an outer end position guided on the support plate 20 'at a distance from the second wall segment 26 (FIG. 2a), so that between the first and second wall segments 25, 26 a free support surface for Placement of a metal bolt 10 and a longitudinal opening 11 is formed.

The metal bolt 10 is brought up by means of the transport container 30 'and by tilting the same between the first and second wall segments 25, 26 on the support plate 20 ' discontinued. The first wall segment 25 is subsequently driven by means of a hydraulic drive Top 21 'of the support plate 20' pushed against the metal bolt 10. The first wall segment 25 then pushes the metal bolt 10 into the filling vessel 13 'and is in a inner, closed end position, in which the first and second wall segments 25, 26 a U-shaped to circular surrounding the inserted metal bolt 10 Form cavity 14 (Fig. 2b). Subsequently, the metal bolt 10 can by means of a Casting piston are driven into the filling chamber cavity (not shown in Fig. 2).

Fig. 3 shows a schematic partial view of a vertical through the concentric central axis x the filling chamber 42 (filling chamber longitudinal axis) running longitudinal section of a horizontal thixoforming system 40 for the production of thixotropic molded parts. The horizontal thixofrom system 40 has a horizontally lying cylindrical filling chamber 42 with a Filling chamber cavity 44. One provided as an integral unit of the filling chamber 42 and the filling device 12 described above is used to insert the metal bolt 10 into the filling chamber cavity 44. The displacement of the metal bolt 10 from the filling vessel 13 in the filling chamber cavity 44 takes place by means of an arranged in the filling chamber 42 Casting piston 46, which is movable in the direction of the filling chamber longitudinal axis x.

The horizontal thixoforming system 40 also contains a thixoform 49 with a fixed one Mold half 49 and a movable mold half 50, which together form the mold cavity 54 form.

To accommodate the axial, i.e. in the direction of flow of the thixotropic metal alloy forces acting on the sprue, the fixed mold half 48 of the thixoform 49 is on one Shield 52, i.e. a strong wall element of the thixoform system. The shield 52 and the fixed mold half 48 have a continuous opening for receiving the filling chamber 42 on. The shield 52 also has a directed against the continuous opening and a groove-shaped recess 62 arranged at the edge of the thixoform 49. This groove-shaped Recess 62 serves to receive a complementarily shaped stop rib 60 of the filling chamber 42. The groove-shaped recess 62 of the shield 52 and the molded one Stop rib 60 of the filling chamber 42 are expediently radially symmetrical educated. Now the filling chamber 42 into the through opening of the shield 52nd inserted so far that the stop rib 60 completely in the groove-shaped recess 62nd engages and the fixed mold half 48 is also set flush with the shield 52, so takes the shield 52 the axial during the thixoforming in the filling chamber 42 Powers up.

The preheated thixotropic metal bolt is used for forming by means of a casting piston 46 using high pressure from the filling chamber 42 through the sprue 56 in the Mold cavity 54 pressed and formed into a molded part.

The horizontal thixoforming system 40 can additionally have a device for oxide layer separation, in particular an oxide layer separation in the execution of an oxide knife included (not shown in the drawings).

Claims (19)

Filling chamber (42) of a horizontal thixoforming system (40) for receiving a preheated thixotropic metal bolt (10), the filling chamber (42) having a filling chamber cavity (44) and a filling device (12) with a filling vessel (13) for inserting the thixotropic metal bolt ( 10) in the filling chamber (42) and the filling vessel (13) has a cylindrical hollow body with an elongated cavity (14) and a longitudinal opening (16) running along a longitudinal axis of the filling chamber (x) for inserting the metal bolt (10) transverse to the longitudinal axis of the filling chamber (x ) in the filling vessel (13),
characterized in that
a support element (20) with an upper side (21) for placing a preheated thixotropic metal bolt (10) abuts or is attached to the filling vessel (13), so that a metal bolt (10) moves in a controlled manner from the support element (20) through the Longitudinal opening (16) can be rolled or pushed into the filling vessel (13). Filling chamber according to claim 1, characterized in that the longitudinal opening (16) is delimited by longitudinal edges (17) and the support element (20) lies against the filling vessel (13) along a longitudinal edge (17), preferably the lower longitudinal edge (17) is flanged to this. Filling chamber according to one of claims 1 to 2, characterized in that the orientation of the longitudinal opening (16) is such that the leading through the longitudinal opening (16) and the filling chamber longitudinal axis (x), running along the filling chamber longitudinal axis (x) and the cavity ( 14) in two uniform halves dividing the directional plane (E) with a horizontal plane (H) an angle of 5 ° to 90 °, preferably from 10 ° to 60 °, and in particular from 15 ° to 50 °, based on a full circle of 360 ° , includes. Filling chamber (42) of a horizontal thixoforming system (40) for receiving a preheated thixotropic metal bolt (10), the filling chamber (42) having a filling chamber cavity (44) and a filling device (12) with a filling vessel (13) for inserting a thixotropic metal bolt ( 10) in the filling chamber (42), in particular according to claim 1,
characterized in that
the filling vessel (13 ') consists of a first wall segment (25) and a second wall segment (26) movable transversely to the longitudinal axis (x) of the filling chamber, and the first wall segment (25) on one at a connection point (27) between the first and the second Wall segment (25, 26) attached to or resting on the end and away from the filling vessel (13 ') support element (20') is displaceably positioned relative to the second wall segment (26) and the first wall segment (25) is in a relative inner, closed end position with the second Wall segment (26) forms a cylindrical cavity and the filling vessel (13 ') forms a longitudinal opening (11) in a relatively outer, open end position of the first wall segment (26), so that a metal bolt (10) moves in a controlled manner from the support element (20 ) can be rolled or pushed through the longitudinal opening (11) into the filling vessel (13). Filling chamber according to claim 4, characterized in that the connection point (27) is arranged between an upper longitudinal edge (17) of the filling vessel (13 ') and the low point of the cavity (19), preferably at the lowest point of the cavity (19), and the filling vessel (13') divided into a first and a second wall segment (25, 26). Filling chamber according to one of claims 4 to 5, characterized in that in an inner, closed end position of the first wall segment (25) the filling vessel (13 ') forms a cylindrical cavity with a longitudinal opening with longitudinal edges (17) running along a longitudinal axis of the filling chamber (x). . Filling chamber according to one of claims 4 to 6, characterized in that the connection point (27) divides the filling vessel (13 ') at the lowest point in the cavity (19) into first and second wall segments (25, 26) and the support element (20) with the deepest one Point of its upper side (21) at the level of the cavity low point (19) at the connection point (27) and the first wall segment (25) includes a central angle of 90 ° to 120 °, based on a full circle of 360 °. Filling chamber according to one of claims 1 to 7, characterized in that the upper side (21) of the support element (20) with a horizontal plane (H) has an angle α of greater than -10 °, preferably greater than -5 ° and in particular equal or greater than 0 ° and less than 60 °, preferably less than 35 ° and in particular less than 25 °, based on a full circle of 360 ° (angular degrees), the slope of the top (21) to the filling vessel (13 ) is positive at an angle of less than 0 ° and negative at an angle of greater than 0 °. Filling chamber according to one of claims 1 to 8, characterized in that the elongate cavity (14) of the filling vessel (13) is of constant cross-section along the longitudinal axis of the filling chamber (x) and describes a partial circle or a partial oval and adjoining, mutually parallel walls has or adjoining walls which are at an acute angle to one another in such a way that the elongated cavity (14) widens from the inside to the outside, and this partial circle or partial oval preferably has a central angle of 120 ° to 180 °, based on a full circle of 360 °, includes. Filling chamber according to one of claims 1 to 9, characterized in that the elongate cavity (14) of the filling vessel (13) has a U-shaped to semicircular cross section. Filling chamber according to one of claims 1 to 10, characterized in that the top (21) of the support element (20) is flat and the support element (20) is arranged such that its top (21) with an horizontal plane (H) an acute angle of greater than 0 °, preferably greater than 5 °, in particular greater than 15 ° and less than 45 °, preferably less than 35 °, in particular less than 25 °, based on a full circle of 360 °. Filling chamber according to one of claims 1 to 11, characterized in that the metal bolt (10) with a central surface portion including a central angle of at least 45 ° and at most 180 °, in particular from 90 ° to 120 °, based on a full circle of 360 ° of the inner wall (23), so that the soft metal bolt (10) can be stored in the filling chamber (42) without being deformed and can be displaced in the direction of the longitudinal axis (x) of the filling chamber. Filling chamber according to one of claims 1 to 12, characterized in that the wall or a wall segment (26) of the filling vessel (13) consists of a composite material, this composite material having an outer wall (24) made of a high-melting metal and this outer wall ( 24) receives an inner wall (23) made of a ceramic material. Filling chamber according to one of claims 1 to 13, characterized in that the high-melting metal is copper or a copper alloy or an iron or a carbon-containing metal, and is preferably steel, in particular tool, hot work or stainless steel and the ceramic material is an Al ₂ O ₃ , Al ₃ O ₄ , BN, SiC, Si ₃ N ₄ , MgO, TiO or ZrO ₂ contains or consists thereof. Method for transferring a preheated thixotropic metal bolt (10) from a transport device into the filling chamber (42) of a horizontal thixoforming system (40) via a filling device (12) according to claims 1 and 4,
characterized in that
the metal bolt (10) is deposited by means of a transport device (30) in the direction of the longitudinal axis of the filling chamber (x) onto the top (21) of a support element (20) which is in contact with or attached to the filling vessel (13) and the metal bolt (10) is placed over the support element (20 ) is rolled or pushed transversely to the longitudinal axis (x) of the filling chamber, if necessary by pushing it with a plunger, a wall segment or the transport device, in a controlled movement through a longitudinal opening (16) into the filling vessel (13) and a piston (46) pushes the metal bolt ( 10) from the filling vessel (13) into a filling chamber cavity (44) of the filling chamber (42). A method according to claim 15, characterized in that the top (21) of the support element (20) includes an acute angle of greater than 0 ° with a horizontal plane (H) and the top (21) has a negative slope in the direction of the filling vessel (13) and the metal bolt (10) rolls after being placed on the support element (20) with or without abutment in the filling vessel (13). Method according to one of claims 15 to 16, characterized in that the transport device is a transport container (30) and the metal bolt (10) is conveyed to the filling device (12) by means of transport container (30) and the transport container (30) directly on or immediately above the support element (20) is tilted and the metal bolt (10) rolls out of the transport container (30) onto the top (21) of the support element (20) and the metal bolt (10) follows the force of gravity and, if necessary, by means of a plunger, a wall segment (25) or through the transport container (30) itself rolls over the top (21) into the filling vessel (13). Method according to one of claims 15 to 17, characterized in that the metal bolt (10) rolls over the support element (20) and along the cavity wall adjoining the support element (20) into the cavity (14) of the filling vessel (13). Method according to one of claims 15 to 17, characterized in that the filling vessel (13 ') consists of a first wall segment (25) and a second wall segment (26) movable transversely to the longitudinal axis (x) of the filling chamber and the first wall segment (25) a support element (20 '), which is attached or abutting at the end at a connection point (27) between the first and the second wall segment (25, 26), and the connection point (27) the filling vessel (13') between the upper longitudinal edge (17) divides the filling vessel (13) and the cavity low point (19) into a first and second wall segment (25, 26) and the first wall segment (25) for inserting the metal bolt (10) is guided into an outer open end position on the support element (20 ') and the metal bolt (10) between the first and second wall segments (25, 26) is placed on the support element (20) and the first wall segment (25) over the top (21 ') of the support element nts (20 ') is pushed against the metal bolt (10) and the first wall segment (25) pushes the metal bolt (10) into the filling vessel (13') and is moved into an inner, closed end position in which the first and second wall segments (25, 26) form a cylindrical cavity (14 ').

Images