DE8913747U1 - Device for melting and casting precious metals, in particular titanium and alloys consisting of these metals - Google Patents

Description

Patent attorneys· ·:"/."": ANDRAE · FLAÖH -'HÄÜ'G · KNEISSL

EUROPEAN PATENT ATTORNEYS

, Patent Attorney Dlpl.-Phyi. Flach. Priraregantanitf ■ 24. P-MOO Rofnhalm .

ROSENHEIM Dipl.-Phys. Dieter Flach Prlnzregantenstraße 24 D-8200 Rosenheim Telephone: (08031)17352 Fax: (08031) 17972 (Gr.3/2) Telex: 5216?81 afho d Telegram: Physicist Rosenhelm

MONKS

Dipl.-Chem. Or. Steffen Andrae D ⁽ pl-Ing. Dietmar Haug (Qöppingen) Dipl.-Chem. Dr. Richard Kneissl Steinstrasse 44

D-8000 Munich 80 Phone: (089) 482089 Fax (089) 4489263 (Gr. 3/2)

Telegram: pagema Munich

301 P6

Device for melting and casting precious metals, in particular titanium and alloys consisting of these metals

The invention relates to a device for melting and casting precious metals, in particular titanium and alloys consisting of these metals according to the preamble of claim 1.

[/J Device systems, especially for dental technology, are well known in which precious metals and their alloys are melted and then placed in a muffle with the appropriate

10 can be cast with sufficient investment material.

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Hypobank Rosenheim (bank code 70020001) account no. 0210&idiagr;8288°&bgr;* " ' Postcheckamt München (BLZ 70010080) Account no. 327284-807

These devices are therefore particularly suitable for model casting. The known devices can be equipped with optical casting temperature detection and microprocessor program sequence controls.

More compact arrangements also allow vacuum die casting.

In addition to a stand-alone unit with the required electronics, common devices have a device housing that can be pivoted around an axis and in which the heating device for a crucible for melting a precious metal or a corresponding alloy is housed. The casting cylinder with the required mold can also be housed in the completely lockable housing. After the metal alloy or metal to be melted has been added or after the device housing has been closed, the housing can be flooded with argon at the latest then or beforehand in order to then begin the melting process. After the desired temperature has been reached, the crucible can be pivoted, for example by rotating it around the horizontal axis, so that at least one component of it is above the casting cylinder, so that the flowable melt now flows into the casting mold.

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In principle, devices are also known that enable the casting process to be carried out in a vacuum atmosphere under pressure.

The melting and casting equipment offered today, especially for dental technology, has heating devices for

the crucible, which are so low that titanium cannot be melted with them. But even if correspondingly higher temperatures could be achieved, the desired and required smooth surface structure on the casting model would not appear when casting titanium, as is actually required.

A The object of the present invention is therefore to provide the $

S to overcome disadvantages according to the state of the art and

a device for melting and casting precious metals, ^;

in particular titanium and the associated alloy, with which problem-free and safe melting and casting of optimal casting models is possible, especially in the high temperature range.

-.

The object is achieved according to the features specified in claim 1. Advantageous embodiments of the invention are specified in the subclaims.
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It can be described as quite surprising that *

A significant improvement in the quality of the casting model occurs, especially when casting titanium, if after ■

Melting process: pouring the liquid melt into a f;

heated mold. According to the invention, in the

Device housing a heating device for the casting mold ;|'

This can be done in parallel with the melting ^

or preheated before melting and also kept at a preselected desired temperature during the casting process. Particularly when casting titanium, for example in a temperature range of around 1,800 ⁰ C, it has proven to be advantageous to keep the temperature in the casting mold at around 1,100 ⁰ C.

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The safety of the entire device can be significantly improved by providing an additional protective device for the melting device for the high-temperature crucible as well as a cooling device. The protective device serves primarily to protect the melting device if damage to the crucible occurs at such high temperatures. The cooling device provides additional protection for the melting device, which can also represent a high economic value, especially if the melting process is carried out using lasers, inductively, etc.

P* Further advantages, details and features of the invention are explained below using an embodiment example with reference to the attached figures. The figures show in detail:

Figure 1: a schematic plan view of the melting and casting device according to the invention

of precious metals, especially titanium;

Figure 2: a schematic side view; Figure 3: a schematic front view;

Figure 4: a partial longitudinal sectional view through the device housing.

Figures 1 to 3 show schematically in plan, side and front views a device 1 for melting and casting metals, metal alloys and in particular titanium.

The device comprises a device housing 3 with the control and switching device located inside. For example, a horizontal double pivot axis 5 is arranged on the central device body, which shows two device housing halves 7'. The double pivot axis 5 or the double shaft leads to a pair of levers 9 arranged on the back of the central body of the device 1, which will be discussed later. Instead of the pair of levers for pivoting the device housing halves 7', pivoting can also be carried out electronically, for example by means of data storage.

As can be seen in particular from Figure 4, one half of the device housing T contains a crucible 11 which is also suitable for the high temperature range, in particular for melting titanium. As is known, the melting temperatures of titanium require heating up to approx. 1,800 ^° C.

A heating or melting device 13 is provided around the crucible 11. This is located in a separate area protected from the crucible 11 by a protective housing 15 and is provided with a holder into which the crucible body 11 is received and encompassed as completely as possible.

The melting unit 13 can be constructed in different ways and can include, for example, a heating coil, an induction coil or a heating device that operates using a laser. Other heating devices are also conceivable.

In the embodiment shown, an induction coil is provided which is arranged around the corresponding recess accommodating the crucible 11.

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In the embodiment shown, a cooling device 19 in the form of a cooling coil is also arranged around the induction coil 17. This cooling device protects the entire melting unit 13 from the high temperature of the titanium or alloy to be melted. The cooling coil 19

h cooling medium flows, preferably in a closed circulatory system, which is external to the device, e.g. by means of a cooling water

8 cooling system. The air circulating in the cooling system

10 de The cooling medium should be free of deposits, preferably not water, in order to avoid limescale deposits

the.

&phgr; In the second device housing half 7 ¹ , the

sK 15 valley area preferably in the form of a muffle

Casting mold 21, in which inside for the production

of a cast an investment with a mold enti'·

appropriate hollow mold. The mold

ir 21 is enclosed by a heating and heating element 25,

H 20 which can also be electrically charged by means of a resistor

f? Stand coil can be heated. By a not further specified in the

The control device housed in the device can adjust the temperature, for example, to 98O ⁰ C to 1,500 ⁰ C, often not

ff more than up to 1,100 ⁰ C.

f -25

A separating and insulating disk 29 provided with a central channel 27 can be arranged between the two housing halves.

i 30 The device works as follows.

With the device _housing halves 7' essentially open and lying next to each other, as shown in Figures 1 and 2

:;', the metal alloy to be melted, especially titanium, can be entered in the desired |£ quantity once in the melting crucible.

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The casting mold with the investment material 23 is introduced into the second device housing half 7'. Both halves can then be flushed or flooded with argon by introducing argon above the device housing halves 7', which are open at the top, in a manner not shown in detail. Since argon is heavier than air, it flows

Then the levers 9 provided on the back of the double shaft or at least one lever

9 is pivoted towards the other in such a way that the lever ■.'■.-.

9 pivot axis 5 in coupling connection a "4,

Device housing half 7' is pivoted so that ; _; j

■.'■;i that a closed device housing 7, as shown in Figure 3 |

or 4, in which the two device housing halves 7' are joined together at their opening area to form a closed device housing 7. The closing process, however, only takes place after the above-mentioned separating and insulating disk 29 has been inserted.

In closed form, the cavity inside the device housing 7, which is initially flooded with argon, can then be sucked out by generating negative pressure via a corresponding vacuum line 31, which is only indicated schematically in Figure 4.

In the initial position during the melting of the metal alloy, the introduced metal or the titanium or the titanium alloy, the arrangement is brought into a position in which the device housing half 7' receiving the crucible 11 lies below the pivot axes 5 in a vertical position or, for example, as shown in Figure 3, in an inclined position.

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As soon as, for example, the titanium introduced has melted by switching on the melting device 13 after heating to, for example, over 1,800 ⁰ C (which can be determined and displayed by an integrated sensor on the device (not shown in detail), the device is now pivoted by pivoting both levers 9 so that the device housing half 7 ¹ with the casting mold comes to lie lower than the pivot axes 5. In other words, due to gravity, the

^xu crucible can flow into the casting mould through the central channel 27. As mentioned, the pivoting of the levers 9 can be carried out not manually but electronically controlled.

Because the casting mold has already been heated to 1,100 ^° C, for example, during or before the casting process, a cold shock that would impair the casting result is avoided, so that the cooling process and the temperature jump from 1,800 ^° C, for example, to approx. 800 ^° C, depending on the preheating temperature set, are mitigated and the casting result is thus improved.

Finally, since an argon pressure line 33 is also provided, the casting process can then take place under pressure.

The device described and the associated apparatus can be used to cast pure titanium or a titanium alloy or other alloys without any change to the metal or alloy structure.

The areas of application range from clinical-medical (e.g. heart valves), clinical-surgical (hip

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joints, etc.), dental-surgical (enosseous implants, subperiosteal implants, etc.) and dental-technical (crowns, bridges, plates and frameworks, auxiliary parts, attachments, orthodontics, etc.) up to the highest technological use in industry.

Deviating from the embodiments shown schematically in the drawings, the device 1 shown there can be housed entirely under a preferably transparent housing that can be closed from the outside, in order to be able to improve the flooding with argon atmosphere in particular.

In the embodiment shown, the cooling device consisting of a cooling coil is shown separately next to the induction coil 17. However, it would also be possible for the cooling coil 19 itself to serve as an electrically conductive induction coil, in other words, in this case the induction coil 19 consists of a tubular coil body through which the cooling medium flows directly for cooling. However, it would also be possible in this embodiment, as in the embodiment shown in Figure 4, to use a second cooling coil if this should be necessary.

Furthermore, it is also possible that, in contrast to the embodiment explained with reference to the drawings, the device housing does not consist of two halves that can be opened in the middle, but that an essentially one-piece device housing is provided, which can be opened once in the area of the upper end face and once in the area of the lower end face. In other words, the crucible can be accessed by opening the upper end face and the casting mold or muffle can be accessed by opening the lower end face, depending on the orientation.

Claims (13)

PATEJ*TAN WASTE j ··":'"· ANDRAE · FLAÖrt ^! 'HÄÜ'Ö · KNEISSL EUROPEAN PATENT ATTORNEYS , P»t«nUnw»U Dlpl.-Phy». FUCH. Prlnzf»g«nl«n»lr. 24. &Ogr;-&bgr;&Zgr;&Ogr;&Ogr; Bo»enh»lni . ROSENHEIM Dipl.-Phys. Dieter Flach Prinzregenienstraße 24 D-8200 Rosenheim Telephone: (0 8031)17352 Fax: (08031) 17972 (Gr.3/2) Telex: 5216281 afho d Telegram: Physicist Rosenheim MONKS Dipl.-Chem. Dr. Steffen Andrae Dipl.-Ing. Dietmar Haug (Göppingen) Dipl.-Chem. Dr. Richard Kneissl Steinstrasse 44 D-8000 Munich 80 Phone: (089) 482089 Fax (089) 4489263 (Gr. 3/2) Telegram: pagema Munich 301 P6 Expectations: 15 1. Device for melting and casting precious metals, in particular titanium and alloys consisting of these metals, with a sealable device housing (7), a melting crucible (11) which can be accommodated in the device housing (7) and a melting device (13), and a casting mold (21) which can be accommodated in the device housing (7), in particular a casting cylinder or muffle with appropriate investment material, into which the melt liquefied in the associated melting crucible (11) can be poured into the casting mold (21) with appropriate alignment of the device housing (7), preferably under an argon atmosphere, characterized in that a warming and heating device (25) is also provided in one of the device housings (7), into which the casting mold (21) can be introduced, whereby it can be brought to a preselectable warming temperature and kept. -01 Hypobank Rosenheim (bank code 70020001) Account No. '6 210M82 $S6 ' Post Office Checking Office Munich (bank code 700100 BO) Account No. 327284-807 2. Device according to claim 1, characterized in that further a protective device at least in the shape of a V _; Protective housing (15) for the melting device (13) in the | the crucible (11) receiving device housing half (7 ¹ ) is provided. p 3. Device according to claim 1 or 2, characterized in that the protective device (15) consists of a protective housing wall surrounding the crucible (11). 4. Device according to claim 1, 2 or 3, characterized in that a cooling device (19) is also provided for cooling the melting device (13), by means of which, in particular at high melting temperatures of up to approximately 1,800 ⁰ C and more in the crucible (11) the melting device (13) on : can be brought and stored at a significantly lower temperature. 5. Device according to claim 4, characterized in that the cooling device (19) consists of a cooling medium; through which the cooling coil (19) flows. 6. Device according to one of claims 1 to 5, characterized in that in the device housing (7) between the crucible (11) and the casting mold (21) a separating and insulating lierscheibe (29) with central channel (27) for the passage ;! the flowable melt can be introduced. 7. Device according to one of claims 1 to 6, characterized in that two associated actuating levers (9) can be used to move both device housing halves (7') from their open position to their closed position, in which the two device housing halves (7 ^' ) are firmly closed together at their opening area, and vice versa, via a double axis (pivot axis 5). -02 8. Device according to one of claims 1 to 8, characterized in that a supply and discharge line for the cooling medium is provided on the device housing half (7 ¹ ) receiving the crucible (11). 9. Device according to one of claims 1 to 8, characterized in that the entire device (1) taking over the standing and control as well as display function with the associated device housing (7) is accommodated in a further completely lockable chamber that can be viewed from the outside, the opening and closing function being operable via the levers (9) from outside the chamber. 10. Device according to claim 6, characterized in that the crucible (11) lies tightly against the separating and insulating disk (29) with its front opening edge. 11. Device according to claim 6 or 7, characterized in that the crucible (11) projects with its opening edge into a funnel which merges into the central channel (27). 12. Device according to claim 6, 10 or 11, characterized in that the separating and insulating disk (29) lies tightly against the front side of the casting mold (21) and/or the embedding compound (23) located therein and/or is provided with a projecting casting attachment facing thereon, which engages in a corresponding funnel-shaped depression. 13. Device according to one of claims 1 to 6 or 8 to 12, characterized in that the device housing (7) is provided with a closable lid in the upper and lower end wall region.