DE7829116U1 - HOT CHAMBER DIE CASTING MACHINE - Google Patents

Description

Hot chamber die casting machine

The present invention relates to a hot chamber die casting machine, those for casting parts from aluminum and its alloys, as well as from zinc, magnesium, copper and theirs Alloys and all other alloys that attack ferrous metals in a liquid state are suitable, and the It allows parts of excellent surface condition without oxide and other inclusions, without contamination Lubricant residues from the pump, with thin walls, with constant high quality, increased strength and without Establish embrittlement by dissolving iron.

In die casting, a distinction is made between two processes, namely the cold chamber process and the hot chamber process. The The former method is characterized in that the liquid metal is poured into a chamber in front of each individual cast is not heated. The second method is characterized by the fact that the pump is heated to the temperature of the liquid metal, and that the working cycle comprises two periods: the inflow of the liquid metal into the mold and then pressing it in.

The main disadvantages of the cold chamber process are:

- Taking a certain amount of oxides with you when transporting the liquid metal from the supply furnace into the pressure chamber.

- Difficulty in the exact dosage of the scooped amount.

- Variable content of oxides, which influences the quality of the parts.

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- Oxidation of the liquid metal during the filling of the press sleeve.

- Contamination from lubricant residues in the press sleeve.

·· No uniform temperature profile during the casting process.

The advantages of the hot chamber process are: 1) Regarding castability:

- Improvement due to the more regular metal temperature when entering the mold.

- Filling the pump without contact between the air and the liquid metal.

- Always the same composition of the liquid metal melt. 2) Regarding production:

- Higher production rate due to better use of the machine, less scrap during the casting itself and also during the secondary operations.

- Elimination of the manual or automatic. Filling the Press sleeve with the ladle.

- Better ways to automate.

- Selectable, controllable and reproducible casting cycle.

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3) Regarding the shape

- Various positioning options.

- Smaller metal print.

- Smaller thermal fluctuations due to faster and more regular cycles, less shrinkage of the cast Parts.

- Longer service life.

After the successes in die casting according to the hot chamber process for lead, tin and zinc alloys by means of a piston pump The use of this technique for aluminum alloys and other corrosive metals and alloys remained blocked because Iron materials quickly attacked by the liquid metal

J- are very limited and therefore the service life of the pump

jj It is true that there is already a casting

! j uses air pressure machine to make the Vox parts

to be able to take advantage of the hot chamber process. Meanwhile, satisfy these casts not because of their porosity and bulk

jS the iron content, which increases the brittleness.

Aluminum die-casting is currently used worldwide using the cold-chamber process practiced, the universal utilization of which is limited by the difficulty of its automation. The hot chamber process with the piston pump is a process of a simpler kind, which is automated as with zinc die casting would allow. This would make production more economical, combined with improved and more uniform production Product quality.

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The liquid aluminum alloys are so corrosive that currently no ¥ arm chamber die casting machine after Pump principle exists, which could be used in practice.

From US Pat. Nos. 3,319,702 and 3,586,095, piston pumps have become known whose parts (piston and sleeve) made of sintered TiB “and ZrB _? are manufactured and which should allow a service life of about 50,000 shots without failure. Endurance tests on Prcduktionsmaschinen have shown, however (see. PW Marshall, Foundry Trade Journal, Nov. 26, 1970, 797) that the lifetime of the essential elements is very low and quite different is (effective use only about 600 to 57,000 shot) _o The main causes for the premature failure of the liner and the piston are the poor resistance of TiB "and ZrB_ to alternating thermal stress and the excessive difference in the expansion coefficients of cast iron and the materials mentioned, which led to impermissible mechanical loosening and decentering in long-term tests. In this case, the increase in the Fe content in the alloy, at 0.2% , was relatively small, but still too high, especially in cases when alloys are to be cast which must practically not contain any iron.

In the JA-PS 7 ^ 07 ^ 523 a pump for the die casting of liquid aluminum is described, which is equipped with a piston and a bushing made of hot-pressed TiC and which should allow 120,000 shots at a pressure of 150 kg / cm. About 150,000 rounds at a pressure of 120 kg / cm can be achieved if the piston and the sleeve are made of hot-pressed TiC (75 "/ <>) + Si" N, (25 %) ; 160,000 rounds at one pressure from

2
120 kg / cm with a piston and a sleeve made of hot-pressed TiC (52 </ »), Si ₃ N ₄ (25 Yo), TiB ₂ (20 %), CrB ₂ (3 ⁰ Io).

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DE-PS 2 320 887 discloses the use of pump parts made of AlN, alloyed with 0.1 to 10 percent by weight of Y ,, 0 ", La 0 , Sc _p 0", Ce 0 ", Al _p 0" or metallic silicates, known. The pistons and liners produced by hot-pressing these materials have a service life of approximately 100,000 to 130,000 pumping cycles in liquid aluminum alloy.

In a piston pump according to CH-PS 586 58I, the piston made of sintered material and the sleeve or its coating consist of a mixture of carbides or borides, such as boron carbide 10-90 percent by weight, preferably 30-70 %, titanium boride 5-6O%, Zirkoniumbor id 5-60 ° / o, boron nitride 0.5-30 ° / o and possibly 0-5 ⁰ Jo borides of tantalum, molybdenum, tungsten, carbides of zirconium, silicon, tantalum, vanadium, chromium, tungsten, molybdenum, nitrides of aluminum, silicon, titanium, zirconium, oxides of aluminum and beryllium.

The porosity of the sintered material is less than 5 ° / ° t, its flexural strength is greater than 400 kg / cm and its hardness

ο
greater than i400 kg / mm.

Tests have been carried out with pistons and sleeves made from these materials. In some cases, the central body of cast iron, which was provided with a protective coating made of graphite was 0, through the liquid metal (Al, 1.5-3.5 / o Cu, 10.5-12 ⁰ J ₀ ° Si, corroded 3 Mg, 1 ° / o Zn, 0.9% Fe ...) of 110,000 to I60.OOO Einfülloperationen at a pressure of I5O to 25O kg / cm, but no signs of corrosion to the sleeve and on the piston were determined. These pumps can only be used for casting zinc and magnesium alloys, but not for other aggressive metal alloys.

Various materials have therefore already been proposed which are suitable for the manufacture of pistons and sleeves appear, but they are not yet entirely satisfactory. the

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Lifespan · of the pump and the quality of the cast parts "but remain through, premature corrosion and wear and tear the pump parts are limited.

The problems to be solved in order to realize a die casting machine with a piston pump correspond to the four components such a pump:

- Pistons and liner are subject to corrosion and abrasion as well as mechanical stresses and influences such as loosening, Centering and other, subject.

- The seat of the pump and the pouring neck are subject to corrosion and erosion.

! - The pouring mouth is due to corrosion, erosion, oxidation

Air as well as thermal and mechanical alternating loads.

- The crucible is subject to corrosion and oxidation by air.

The materials required to implement such a pump must be resistant to corrosion by liquid aluminum as well as to abrasion and erosion. They must be quite hard and have thermal expansion coefficients close to those of ferrous metals. In addition, for certain of the aforementioned uses, they must be resistant to oxidation and thermal and mechanical alternating loads. Finally, it is advantageous to have materials that are not wetted by the liquid metal and that have the highest possible density. Ä

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The following table shows some of the known properties of the materials that best corrosion by liquid aluminum are resisting, compiled (where zvoc design of the pump also other characteristics play a role) _o

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WLRKSTOFP fcthNE T TUNGE
WINKtL FUEF?
LIQUID
Al IiAtRTE EXPANSION
COEFFICIENT
0 - 75O ⁰ C
1O ^-6 CI RESISTANCE
ABILITY
against Oxi
dation WIüERSTANUS-
l AEIIK (KE IT
(»ΕΠΕΝ THERMAL
SHOCK SHOCKS ι r-containing:
jusaeisen 250-700 HB 9-10 mediocre M-containing E. lflO-350 HB 15.5 » ..r-f1etall in average. 9.5 Well Well ..raphite ' small amount small amount small amount aueg »« »! chMut ¹¹ -Λ 157 ° (λ, 700 ° Ο .d!) U0-3000 2.45-3.2 jusgezcichnel Il <UN 138 ^O (90Q ° C) 1250 HV 5.6 Il f ( 170 ° (1000 ° C) small amount 12-13 in the middle a-Al-fj-0 small amount high Well mediocre 20U0 HV ß, 1-8.3 .jusgezuichnet caught; Iu Ü ■ 1 »-20UU HV "10 · ■ juagezeichntat U titanate goring mittelniäsa 0 -1.5 tf tr ■ tumatite » small amount 7-8.5 II ' Well lbU ° (^ .7U (J ⁰ C)
140 ° (9U0 ° C) ^ 34UU HV 4.6-6.3 Well small amount rb, L60 ° l ^ 700 ⁰ C)
LOS {900 ° C) ^ 22UO HV 4.5-7 ■ · ·· small amount '»-LflUU HV 5.4 If » IL .48 ⁰ CdOO ⁰ C) ^ 3000 HV 7-8.5 medium IH 35 ⁰ CdOO ⁰ C) ^ 2IJtIQ HV 9.3 ·· ff
t At • ^ 3flUÜ HV 4.7-5.5 dusdrawn Well

'. Al-Li

f f ^ i

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The invention is based on the object of a piston pump of the type under consideration, which are used for die casting by the hot chamber process of parts made of aluminum alloys and other metals and alloys that attack ferrous metals are better suited than the known pumps and has a longer service life than this - preferably more than I5O.OOO shot allows - high reliability and has operational reliability and in particular does not lead to an increase in the iron content of the melt.

In order to achieve the above-mentioned object, it is proposed according to the invention, die casting machines of the type in question Form in such a way that the pump piston and the pump sleeve made of silicon nitride or sialon of high relative Density exist, and further that the remaining with the molten metal in contact items or their Wall surfaces made of a hard, corrosion and erosion resistant material of high density, such as metallic chrome, Nitrides of silicon, aluminum, titanium, zirconium, sialons, borides of titanium, zirconium, chromium, tantalum, molybdenum, tungsten, Carbides of silicon, titanium, zirconium, tantalum, vanadium, chromium, tungsten, molybdenum, oxides of aluminum, beryllium, Aluminum titanate, individually or in mixtures with one another.

Further and in particular structural features of the subject matter of the invention emerge from the subclaims 3 to I3 as well as from the following description of two preferred exemplary embodiments, especially of the pump device of the f

I the die casting machine out, which in Figures 1 and 2 f

are shown in the drawing. Show it: {

Fig. 1 shows a cross section through one in a crucible | built-in pumping device for charging mold j a die casting machine, and j

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2 shows a cross section through a pumping device,

whose pump crucible is connected to a storage crucible.

The part of a die casting machine shown in Fig. 1 consists of the pump crucible 11, in which the liquid metal alloy 12 is located, and the Punip device 13 with the pump housing 14, the pump sleeve 15 and the pump piston 16, the connecting lines 17, a pouring neck 18 eowie dem Gießmundstüclc 19 · The pump sleeve 15 is attached to the bottom of the crucible 11 by means of the pump housing Ik. At its lower linden the pump piston 16, which is designed as a plunger, is in the sleeve 15 and at its upper end

“Guided by means of a piston rod 20. At its lower end

the piston 16 is provided with an inclined surface 21 - or possibly also with channels - the upper ends 22 of which are in the top dead center position of the piston above the upper end face 23 of the pump sleeve 15 lie. This makes it possible that the liquid metal 12 continues to run into the cavity of the pump sleeve when the piston 16 is in its top dead center position is located without this completely out of the socket I5 must be pulled out.

In the exemplary embodiment according to FIG. 1, the pumping device 13 for the molten metal alloy 12 is located in a crucible 11, which is also designed as a storage container. However, as can be seen from FIG. 2, it is also possible to arrange the pumping device 31 in a separate pump crucible 32, namely in the same, shown in FIG. 1, and the pump crucible 32 with a reservoir 33 via a connecting channel Jk or to connect a connecting pipe 35 which lies below the level 3 ° of the molten metal 37 in the crucibles 32 and 33. This can ensure that on the surface 36 of the metal

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melt 37 in the storage container 33 floating oxides, slags or other impurities do not get into the pump crucible 32 reach.

In order to avoid the formation of oxide on the surface 38 of the molten metal in the pump crucible 32, the latter is covered with a cover 3y provided that the interior space 4θ against the surrounding atmosphere concludes. Advantageously, ei <ae opens into this Pipeline 41, by means of which an inert gas is introduced, to the molten metal 37 in the pump crucible 32 against the Shield air. The inert gas used is preferably argon or nitrogen or another suitable gas or gas mixture Application.

To conduct the molten metal 12, which is pressed out of the pump sleeve 15 with the aid of the pump piston 16, serve the connecting lines 17 in the fitting 42 below the pump sleeve 15 as well as the pipes 43, which in the ground 44 of the crucible 11 and in the pouring neck 18 are used.

All these parts consist of the aforementioned materials in order to avoid that the metal melt with corrosive works openly comes into contact. The adjoining tubes 43 of the molten metal channel 17 point towards them Axis inclined surfaces 45, which makes it easier Way to compensate for changes in length caused by their expansion. Located between the individual tubes 42, 43 seals 46, which are preferably made of boron nitride, graphite or chromium. The connector fitting 42 and the tubes 43 are preferably made of aluminum oxide, beryllium oxide or other oxides or oxide mixtures, such as aluminum titanate, Stumatite, a natural aluminum silicate, sialons, aluminum nitride, sintered silicon nitride, metallic chromium or a ceramic-chromium alloy, such as titanium bond-chromium

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Alloy or the like. Can also be made of the same materials. expediently the Pumpengenau.se 14 for the Pumpenbuch.se 15 be made. If desired or necessary, the surfaces in question can be replaced by a. coating made of aluminum nitride or protected by chromium plating or sulfur plating.

The pouring mouthpiece 19 advantageously consists of bite-pressed silicon nitride or hot-pressed sialons or of another material with fitted parts made of the aforementioned materials. In the case of pouring mouthpieces designed in a similar manner, the risk of the formation of a plug of solidified metal alloy after the shot is largely reduced due to the fact that the above-mentioned materials cannot be used by the molten metal. The crucibles 11 and 32, 33 are usually and in a known manner made of cast iron containing aluminum or chromium, which experience has shown to be resistant to corrosion by aluminum. Nevertheless, it is proposed that the surfaces of the crucibles that are considered should be coated with chromium, aluminum oxide or other oxides such as Al "O" -TiO _p , simple or mixed borides such as ZrB ", CrB ₂ , AlN, Si Nj ₁ , BN or nitrides, such as AlN, Si “N ^, BN, sialons or the like to protect.

As far as connecting screws kj made of steel are used, their heads 48 are countersunk and the blind bores 49 for receiving the screw heads are closed with plugs 50 made of corrosion and erosion-resistant materials, such as S "N. , AlN, sialons, BN, metallic Cr, TiB ,,, ZrB _p , A1 "O", BeO, aluminum ti tanate, stumatite, graphite or the like.

Even if the die casting molds, the machine is less powerful one Corrosion by the molten metal alloys are subject, especially if they are made of cast iron or a

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are made of special steel, then it is advantageous to their relevant surfaces by applying To protect coatings made of suitable materials, and the moreover have the task of improving the surface quality of the castings, facilitating their demolding and to increase the life of the molds. Silicon nitride, aluminum nitride, Sialons, boron nitride and graphitic or pyrolyzed Carbons that should be applied to the surface in sufficient thickness.

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Claims (12)

Expectations Machine for the production of die-cast parts using the hot chamber process for casting parts made of aluminum or aluminum alloys, zinc, magnesium, copper or their Alloys, such as those alloys which are in liquid Condition ferrous metals attack, consisting of a die Melt containing storage crucible, a piston pump and a casting mold, the piston pump having a crucible, a Having a piston and a pump sleeve, characterized in that that the pump piston (i6) and the pump sleeve (15) are out Silicon nitride or consist of Si-Al-O-N high specific gravity. 2. Machine according to claim 1, characterized in that the remaining individual parts coming into contact with the melt or their wall surfaces made of a hard material of high density, resistant to corrosion and erosion, such as metallic Chromium, nitrides of silicon, aluminum, titanium, zirconium, sialons, borides of titanium, zirconium, chromium, tantalum, molybdenum, Tungsten, carbides of silicon, titanium, zirconium, tantalum, vanadium, chromium, tungsten, molybdenum, oxides of aluminum, Beryllium, aluminum titanate, individually or in mixtures with one another, exist. MUNICH: TELEPHONE (08β) 390ΒβΟ CABLE: PROPINDUS -TELEX 00 24 244 BERLIN: TELEPHONE (030) 831SOBB CABLE: PROPINDUS -TELEX Ol 84 007 7829116 01/25/79 IMI * » 11th 3. Machine according to claim. 1 or 2, characterized in that that the pump (i3 »3i) with the ground or the viand des Pumps or the storage riser (11,32) firmly connected is and forms a unit with it. 4. Machine according to claim ₃ characterized in that the 3j Pumpontiegel (32) and the supply crucible (33) (3 ^) are connected to each other and separated by a below the molten metal level channel. 5. Machine according to claim 3j, characterized in that the pump crucible {jk.) Is sealed from the atmosphere and that in the interior of the pump crucible (32) above the molten metal a pipe \ h \ ) for supplying an inert gas and a lockable vent line opens . 6. Machine according to claim 3j, characterized in that the upper face of the pump sleeve (13) or the pump.Tigehäuses (i4) lies below the molten metal level « 7. Machine according to claim 3> characterized in that the The lower end of the pump piston (16) is constantly in the Pump sleeve (15) is guided. 8. Machine according to claim 7j, characterized in that the Pump piston (16) is provided at its lower end with an inclined surface (21) or with channels, the upper ends (22) in the top dead center position of the piston oil (16) above the upper end face (23) of the pump sleeve (15) lie. Characterized 9 · machine according to claim 1 or 2, c-'adurch that the pump sleeve (15) i ⁿ a pump housing (i4) is seated, which in particular from Stumätit, graphite od "dg, l. Material. 7829116 25.0179 -3- 10. Machine according to claim 1 or 2, thereby connected § | net that the molten metal lines f or channels (17) made of fittings (42) or pipes (43) ί consist of corrosion and erosion-resistant material or with a coating made of these materials |. I. 11. Machine according to claim 1 or 2, characterized in that the casting mouthpiece (19) consists of silicon nitride ϊ or Si-Al-ON high density or with adapted I Parts made from these materials are protected. I. 12. Machine according to claim 1 or 2, characterized gekennzeich- \ net, that the sealing elements (46) and the plug (50), in particular boron nitride, graphite, Stumatit od * the like. % Materials. f 13 «Machine according to claim 1 or 2, characterized in that the pump pan and the storage pan (11, 32, 33); k as well as the casting molds with firmly adhering protective coatings; in particular made of silicon nitride, aluminum nitride, j> " Sialons, boron nitride or carbon, individually or in ; Mixtures with one another, are provided. 1 7829116 25.01.7S