EP0761345B1 - Hot chamber die casting machine - Google Patents

Abstract

The machine comprises a melt container (3) with a riser bore (4) and a conical holder (5), a nozzle (8) and a nozzle heating unit. This unit is an inductively operating heating unit (12, 13, 14) located in a region (11) of the holder (5). It is driven at medium frequency (or a frequency lying at the lower boundary of high frequency), and is air-cooled.

Description

The invention relates to a hot chamber die casting machine for Processing of magnesium melts, with a casting container with a riser hole with a conical mouthpiece and with a nozzle attached to the mouthpiece, as well as with a Heating device for heating the nozzle.

In the hot chamber casting process, the casting container is located and the casting piston of the casting unit in the liquid metal. Thereby the economy of the hot chamber process is significant higher than with the cold chamber process.

It is also known that the material magnesium is easy to cast and due to its low weight for many applications interesting is. The processing temperature of However, depending on the alloy, magnesium is between 630 ° C and 660 ° C. Because of this high temperature, it becomes necessary in hot chamber die casting machines of the type mentioned to provide heating for the nozzle and the casting tank. It is known for this purpose gas heating for the nozzle and the casting container approach to provide. However, this leads to certain disadvantages. On the one hand there is an open gas flame, for safety reasons must be monitored. It’s also difficult heat the nozzle with a constant temperature. This can lead to deformation, in particular to bending the nozzle. The gas flame heating can also decarburization of the very expensive material of the nozzle and casting tank occur. It is therefore on the nozzle and on the casting tank a temperature control necessary to the lifespan not to shorten the wearing parts unnecessarily. In particular open flames are off when processing magnesium Unwanted security reasons.

Although heating systems have already been proposed, the Provide inductive high-frequency heating in the area of the nozzle. However, even with these proposals the approach of the Pouring container for the arrangement of the nozzle heated with gas. In terms of the gas heating then used apply the above Disadvantage. Since the inductors in high-frequency heating need to be cooled with water, there is also a risk that water and magnesium together in an undesirable way react.

DE-A 24 25 067 proposes a casting device for casting of magnesium alloys on hot chamber die casting machines before, but uses one perfectly for this purpose casting container arranged outside the crucible with siphon hole and nozzle. This casting container is with a pressurized filling chamber in the crucible over a Ascending pipe and with the crucible via an overflow pipe connected.

This configuration is chosen there to ensure that the degree of filling of the mold regardless of the level of the melt in the Crucible is always the same, without the need for complex monitoring and adjustment of this melt level is necessary. The pouring can with nozzle, the part outside the crucible of the riser pipe and the overflow pipe must be due to this Arrangement to be heated, what with an electric induction heater happens. Since this to avoid a Overheating is likely to be cooled with water same disadvantages as described above.

From DE-OS 21 41 551 is an air-cooled nozzle for metal casting devices known in which the nozzle has a electric resistance heater is heated. You have to get there an overheating of the nozzle between the "shots", where one in the substantial empty nozzle is present, its electrical resistance is larger than the line filled with the metal, one Air cooling is provided, which is placed around the nozzle Mantle flows in channels between turns of a helically wound rod made of round material be formed with an outer sleeve and an inner Sleeve forms the walls for the air duct. The Electrical resistance heating takes place there in that the feed pipe and the nozzle itself with an energy source be connected and so directly as electrical resistance serve.

Finally, EP 0 662 361 A1, from which the preamble of claim 1 is based, is a casting process known in which you have a casting sleeve with one in your Provides internal moving pistons and outside of this sleeve provides a series of electrical control rods, which in turn are surrounded by a wall around which an induction coil is wrapped. The main thing there is to do that to keep potting material in a semi-solid state. For this purpose, very low ones are used in some cases Frequencies, e.g. between 300 and 1,000 Hz for exposure of the induction coil, but at the same time suggests a To avoid overheating of the electrical conductor elements to manufacture these as straight hollow tubes made of stainless steel, embed them in an insulator and cool them with water. The pouring device shown there is not a hot chamber die casting machine. The arrangement and the Operation of such facilities are also very expensive.

The present invention is therefore based on the object in a hot chamber die casting machine for processing Magnesium smelting to propose a heating system with on the one hand, simple temperature monitoring is possible and with which the desired high temperatures can be achieved are, but without compromising security.

To solve this problem is in a hot chamber die casting machine of the type mentioned that the Mouthpiece area of the casting container and the nozzle an inductive working heater is assigned, its inductors consist of externally insulated pipes with medium frequency or with one at the lower limit of the radio frequency frequency applied and air flows through it are. The invention is based on the one hand on the consideration that also produce relatively low frequencies the necessary heating are sufficient and that you can get by with a lower cooling capacity, that can be caused by air. The danger that water and Reacting magnesium is safely excluded in this way. The inductive heating can also be done proportionally simple way of even heating Reach nozzle and pouring container attachment and temperature controlled carry out. The operating frequencies for the heater are between 8 kHz and 15 kHz. The configuration according to the invention also enables a relative easy manufacture of induction heating and cooling equipment. At one end of the tubes, an air inlet and an air outlet valve is arranged at the other end be, the latter more or less temperature controlled can open, so that also on relatively simple Controlled air cooling of the inductors can be effected can.

In a further development of the invention, the tubes can form sleeve bodies be wound, then several each on cylindrical Parts of the device to be heated pushed on can be. In further training this idea can ever one of the sleeve bodies onto one in the area of the mouthpiece cylindrical approach of the casting container, on the area of this casting container adjacent area of the cylindrical nozzle and pushed onto the nozzle in the area of their mouthpiece his. These sleeve bodies can be moved on adjust different areas.

In a further development of the invention, this can be done on the casting container approach put on the sleeve body this approach protrude outside and at least the connection area of the nozzle surrounded outside. To determine any leakage too can, in further development of the invention within the Pouring sleeve body protruding and between this and the nozzle has a monitoring unit for blooming magnesium oxide be provided, which is useful as a ring with a Contact loop is formed. Although therefore from the casting tank continuous heating from to the nozzle mouthpiece the risk is largely excluded, that leaks are not noticed during nozzle assembly and magnesium leaks.

In order to make the seal as good as possible, in Development of the invention of the conical connection area of the Nozzle with an O-ring for sealing in the area of the conical Mouthpiece of the casting container and it is possible to seal the casting container cover from the from this protruding part of the pouring tank, i.e. so below the cylindrical neck, one between two To provide flange rings with clamped sealing cord. These measures contribute to the safety of the now inductively heated Casting unit at.

To prevent the penetration of spraying during the casting process Can prevent magnesium in the area of inductors be provided in a development of the invention that at least the inductor assigned to the nozzle on its to the casting container facing end with a the front end of the to Mouthpiece area extending inductor overlapping edge is provided. This measure can prevent the ingress of possibly magnesium spraying backwards during the die casting process in the area between or under the inductors be avoided. In training the thought of the present The inductor assigned to the nozzle can also be invented have a conical outer contour, from the outset magnesium may splash backwards is derived to the outside.

In a further development of the invention, it can be towards the mouthpiece area trending inductor with a the front end of the on the cylindrical approach of the mouthpiece area of the seated inductor overlapping edge. This edge can be easily formed by a flange that with one towards the front end of the nozzle and the cylindrical one Area of the inductor sloping Ring surface is provided. This ring area also serves as a deflecting surface for any splashing magnesium.

In a further advantageous development of the subject of the main patent can be found in the area of the crucible cover a ring inductor placed around the casting container can be provided, the one to equalize the temperature and to one leads to higher procedural security.

Fig. 1

eine schematische Schnittdarstellung des Austrittsbereiches einer Warmkammer-Druckgießmaschine nach der Erfindung,

Fig. 2

die vergrößerte Darstellung des Bereiches der eingesetzten und abgedichteten Düse mit der erfindungsgemäßen Beheizung,

Fig. 3

eine schematische Stirnansicht der dem Ansetzbereich der Düse und des Gießbehälters zugeordneten Beheizungseinrichtung,

Fig. 4

eine schematische perspektivische Darstellung des Aufbaues der zur Beheizung vorgesehenen Induktoren,

Fig. 5

eine vergrößerte Darstellung des Bereiches der eingesetzten und abgedichteten Düse mit der erfindungsgemäßen Beheizung ähnlich Fig. 2 und

Fig. 6

den Bereich der Tiegelabdeckung mit einem um den Gießbehälter gelegten zusätzlichen Ringinduktor.

The invention is illustrated in the drawing using exemplary embodiments and is explained below. Show it:

Fig. 1

2 shows a schematic sectional illustration of the outlet area of a hot chamber die casting machine according to the invention,

Fig. 2

the enlarged representation of the area of the inserted and sealed nozzle with the heating according to the invention,

Fig. 3

2 shows a schematic end view of the heating device assigned to the attachment area of the nozzle and the casting container,

Fig. 4

2 shows a schematic perspective illustration of the structure of the inductors provided for heating,

Fig. 5

an enlarged view of the area of the inserted and sealed nozzle with the inventive heating similar to Fig. 2 and

Fig. 6

the area of the crucible cover with an additional ring inductor placed around the casting container.

In Fig. 1 is part of a hot chamber die casting machine shown that is used to process magnesium. The liquid magnesium is at temperatures of approx. 630-680 ° C within the container, not shown in detail (1). In this container (1) protrudes through a cover (2) a casting container (3) with a riser hole (4) with a cone-shaped mouthpiece (5). in the Casting container (3) is also not a closer shown casting piston, which is known via the piston rod (6) Introduced into the casting cylinder (7) from above is that from the liquid container (1) with the the amount of liquid that is poured out before the piston reaches the filler opening completes with its movement and the liquid Push the metal up through the riser hole (4).

A is inserted into the mouthpiece (5) of the casting container (3) Nozzle (8) with its mouthpiece (9) into the sprue area the form (10) is sufficient, which is only indicated schematically is.

According to the invention is now on the approximately cylindrical approach (11) of the casting container (3) a sleeve-shaped inductive Radiator (12) pushed on. Two more sleeve-shaped inductive Radiators (13 and 14) are on the middle area the nozzle (8) or on the area of the mouthpiece (9) of the nozzle (8) postponed. This can be done in that the sleeve body (12) is pushed on before the nozzle (8) is installed is that then the nozzle (8) in its conical connection opening (5) is inserted and then the two sleeve bodies (13 and 14) can be pushed onto the nozzle. A separate one Attachment is not necessary because of the sleeve body (13 and 14) because of the slight inclination of the nozzle (8) are held by themselves and the sleeve body (12) the also slightly sloping approach (11) even without a separate one Fastener holds. All radiators (12, 13, 14) can since a fastening is missing, moved very slightly by hand in order to achieve the optimal temperature in the corresponding areas.

The sleeve body (12) is placed on the shoulder (11) that it protrudes from the end of its face. The sleeve body (12) also towers above a mother (15) who is to be used later Disassembly of the nozzle (8) is screwed onto this, as well as one Monitoring device located on the inside of the sleeve body (12) in the form of a contact loop Ring (16) is arranged. To the mouthpiece (9) of the nozzle (8) lies in front of the front end of the sleeve body (12) Mudguard (17), the unwanted intrusion of possibly to prevent magnesium melt splashing backwards.

The monitoring device (16) is used in the exemplary embodiment to do so, between efflorescence in the cavity (18) the sleeve body (12) and the nozzle (8) to detect the for example due to a leak between the approach (11) and the nozzle (8) or due to leaks in the area of the neck (19) of the casting container (3) and thereby in the area inside the sleeve body (12) Magnesium could occur.

Fig. 2 shows that one for better sealing between approach (11) of the casting container (3) and nozzle (8) an O-ring (20) has applied the cone area of the nozzle (8). In the area of Neck (19 of the casting container (3) is a circumferential sealing cord (21) provided between two flange rings (22 and 23) is clamped and thus the required seal between the cover (2) for the molten metal and the Neck (19) of the casting container (3) causes. The flange ring (22) is firmly welded to the cover (2). The Flange ring (23) consists of asbestos-free ceramic material. This ensures that the inductive field is not disturbed becomes. Otherwise the heating effect can be optimally used become.

3 and 4 together with FIG. 2 show that the Sleeve body (12, 13 and 14), which are designed as inductors are, each made of helically wound and insulated on the outside Copper pipes (24) exist on which, as in Fig. 4 schematically is indicated, both the necessary frequency for Generation of the alternating magnetic field via a corresponding one Generator (25) is created, as well as an application Air in the direction of arrow (26). The one in the direction of the arrow (26) supplied air serves as cooling air for the inductors. It exits via an outlet valve (27) again temperature controlled opens or closes. With getting higher Temperature, which is determined by a sensor, opens that Valve (27) more and more, so that when the tubes (24) in Operation get too hot, correspondingly better cooling done by more air flowing through.

Fig. 4 shows that the copper tubes (24) in simpler Allow to wrap to the sleeve bodies (12, 13 and 14). Of course, the inductors so formed are air-cooled outside, with thermal insulation provided before they are in their corresponding mounting positions be pushed.

The front end of the sleeve body facing the mouthpiece (9) (14) is also provided with a mudguard (28). The Inductors are generated by the generator (25) with a kind of medium frequency supplied, i.e. at a frequency that is in the The order of magnitude is between 8 kHz and 15 kHz. During operation the inductor with such a frequency is air cooling possible, in particular due to the special nature of the Training of the inductors is made possible. Take these measures there is no risk of cooling water with any escaping Magnesium can come into contact. A reaction between Magnesium and water are therefore excluded. The order the monitoring device (16) in turn ensures that the cavity itself, which is not transparent in operation (18) can be monitored safely.

To dismantle the nozzle (8), the sleeve body (14 and 13) after switching off the machine forward from the nozzle (8) pulled down. This can be done easily by hand. The sleeve body (12) is then removed from the attachment (11). pulled down, which can also be done by hand, so that then disassemble the nozzle (8) in the known manner the push-off nut (15) can be actuated. By this configuration also becomes possible, e.g. at a short standstill of the machine the front sleeve body (14) to pull over the tip of the nozzle when it is worn out, see above that then at the start immediately from the first shot again correct temperature is reached at the tip of the nozzle.

Different from the embodiment according to FIGS. 1 and 2 5 that the on the area of the mouthpiece (9) the nozzle (8) pushed on inductor (14 '), the rest of the has the same structure as that explained in FIGS. 3 and 4 Inductors, has a conical outer contour (35), the serves to possibly die-cast between the mouthpiece (9) and magnesium spraying the workpiece outwards derived and from the area of the adjacent inductor (13 ') and on the mouthpiece (11) of the casting container (3) keep the attached inductor (12 ') away. This serves the purpose also that the one facing the casting tank, with the larger one End provided with a diameter of the inductor (14 ') a protruding, circumferential edge (30) having a shoulder (31) overlaps at the front end of the inductor (13 '). Through this Overlap becomes a seal between the adjacent ones Inductors created, which also safely prevents that magnesium in the area between the inductors (13 'and 14') or even in the area between the inductors and the nozzle (8) can penetrate.

The inductor (13 ') in turn is on its the casting container (3) facing end with a flange (36) which for cylindrical outer circumference and to the front end of the nozzle (8) provided with an oblique annular surface (34) is also used as a repellent surface for splashing magnesium serves. This flange (36) is on the inductor (12 ') facing Side with a peripheral edge (32) a recess (33) of the inductor (12 ') overlaps so that A seal between the inductors at this point too is created.

Otherwise, the structure of the hot chamber die casting machine corresponds 5 the structure of that described in FIG. 2 Die casting machine.

6 is in the area of the cover (2) the container (1) for the melt a ring inductor (40) above the seal (21) around the neck of the casting container (3) laid around. This ring inductor (40) can also be constructed like the inductors already described. He is operated at medium frequency.

The ring inductor (40) can be formed in one piece and is then pushed axially over the neck of the casting container (3). But it is also possible to make the ring inductor (40) out of two Build half-shells, each on the outside of the neck of the casting container and then connected to each other become.

This ring inductor (40) is used to ensure that it is as uniform as possible Temperature distribution on the neck of the casting container (3) too to reach. This ensures the safety of the casting process become.

Claims (20)

1. Hot-chamber die casting machine for the processing of magnesium melts, having a casting receptacle (3) having a vertical drilled hole (4) having a mouthpiece (5), arranged in a projection (11) of the casting receptacle, and having a nozzle (8), fixed to the mouthpiece, and having a heating device for heating the nozzle (8), characterised in that there is associated with the projection (11) of the casting receptacle and with the nozzle (8) an inductively functioning heating device (12, 13, 14) whose inductors (12, 13, 14) comprise externally insulated pipes (24) which are acted on by medium frequency or by a frequency which is at the lower limit of the high-frequency range and are passed through by air.
2. Hot-chamber die casting machine according to claim 1, characterised in that the operating frequency for the heating devices is in the order of between 10 kHz and 15 kHz.
3. Hot-chamber die casting machine according to claim 2, characterised in that an air inlet (26) is arranged at one end of the pipes (24) and an outlet valve (27) at the other end, the outlet valve (27) opening to a greater or lesser degree in response to temperature.
4. Hot-chamber die casting machine according to claim 1, characterised in that the pipes (24) are wound to form sleeve elements (12, 13, 14).
5. Hot-chamber die casting machine according to claim 4, characterised in that one of the sleeve elements (12, 13, 14) is pushed onto a projection (11), which is cylindrical in the region of the mouthpiece, of the casting receptacle, one onto the region, that adjoins that casting receptacle region, of the nozzle (8), and one onto the nozzle in the region of the mouthpiece (9).
6. Hot-chamber die casting machine according to claim 5, characterised in that the sleeve element (12) which is pushed onto the casting receptacle projection (11) extends outwardly beyond the projection (11) and externally surrounds at least the connection region of the nozzle (8).
7. Hot-chamber die casting machine according to claim 5, characterised in that the sleeve elements (12, 13, 14) can be adapted to different regions by displacement, in particular by hand.
8. Hot-chamber die casting machine according to claim 5, characterised in that guard plates (17 and 28) are provided in front of the end face, directed away from the casting receptacle (3), of the sleeve element (12), which is placed on the casting receptacle projection (11), and at the outer end of the sleeve element (14) which is pushed onto the mouthpiece of the nozzle (8).
9. Hot-chamber die casting machine according to claim 6, characterised in that a monitoring unit (16) for efflorescing magnesium oxide is provided inside the sleeve element (12), which extends away from the projection (11), and between the sleeve element (12) and the nozzle (8).
10. Hot-chamber die casting machine according to claim 9, characterised in that the monitoring unit is in the form of a ring (16) having a contact loop, which ring (16) is attached to the sleeve element (12).
11. Hot-chamber die casting machine according to claim 5, characterised in that the conical connection region of the nozzle (8) is provided with an O-ring (20) for sealing in the region of the conical mouthpiece (5) of the casting receptacle (3).
12. Hot-chamber die casting machine according to claim 5, characterised in that a sealing cord (21), which is held between two flange rings (22 and 23), is provided for the sealing of the casting receptacle cover (2), opposite the neck (19), which extends therefrom, of the casting receptacle (3).
13. Hot-chamber die casting machine according to claim 12, characterised in that a flange ring (22) is securely welded to the cover (2).
14. Hot-chamber die casting machine according to claim 12 or 13, characterised in that the second flange ring (23) comprises asbestos-free ceramic material.
15. Hot-chamber die casting machine according to claim 1, characterised in that at least the inductor (14') associated with the nozzle (8) is provided, at its end facing towards the casting receptacle (3), with an edge (30) which overlaps the front end of the inductor (13') which extends towards the projection (11).
16. Hot-chamber die casting machine according to claim 15, characterised in that the inductor (14') which is associated with the nozzle (8) has a conical outer contour.
17. Hot-chamber die casting machine according to claim 15, characterised in that the inductor (13'), which extends towards the projection (11) of the casting receptacle, is provided with an edge (32) which overlaps the front end of the inductor (12') which is seated on that projection.
18. Hot-chamber die casting machine according to claim 17, characterised in that the edge (32) projects beyond a flange (36) which is provided with an annular face (34) which extends obliquely in the direction towards the front end of the nozzle (8) and the cylindrical region of the inductor (12').
19. Hot-chamber die casting machine according to claim 1, characterised in that an additional annular inductor (40) is placed around the casting receptacle (3) in the plane of the cover (2) of the container (1) for the melts.
20. Hot-chamber die casting machine according to claim 19, characterised in that the annular inductor (40) is constituted by half-shells which can be put onto the neck of the casting receptacle (3).

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