DE102011120416A1 - Filter for filtering liquid metals in casting system, has filter element filtering liquid metal, surrounded by filter housing and includes form of hollow sleeve, where aperture of filter element extends to opening - Google Patents

Abstract

The filter has a filter housing made of refractory material i.e. metal oxide, provided with an intake port and an exhaust opening. A filter element (1) i.e. hollow dome, filters liquid metal, and is surrounded by the housing. The filter element includes a form of a hollow sleeve with an aperture, where the aperture of the filter element extends to the opening. The sleeve includes a form of a hollow cylinder or a hollow blunt cone, and the housing is formed as a filter housing base part (2) and a filter housing upper part (3), where the base part receives the opening and the filter element. The filter element is made of ceramic material.

Description

The invention relates to a filter for the filtration of liquid metals with a filter housing made of refractory material, which has at least one inlet opening and at least one outlet opening and in which at least one sleeve-shaped filter element is arranged between the inlet and outlet.

Filters for the filtration of liquid metals are already known. In a simple form, such filters are from the DE 3902151 A1 known. The filter housing is designed here as a sprue. The filter element is an inserted into the filter housing disc. The filter element creates two separate spaces for unfiltered liquid metal, the sprue, and for filtered metal.

From the DE 422917 C2 another geometry of a filter housing for the filtration of liquid metals with a filter housing made of refractory material is known, with at least one inlet and an outlet, wherein between inlet and outlet at least one filter element is arranged and the filter housing on the input side an annular channel and the output side an enclosed by the annular channel inner Has collecting space and the filter element between the annular channel and collecting space is arranged. The filter housing consists of a refractory material in the interior of several filter plates a circle or an oval forming are used.

The filtration performance of the known filters is relatively low. They can get stuck quickly (blocking). Furthermore, the casting capacity of the filter is limited. Here, according to the state of the art, it is attempted over long "filter banks" to increase the casting performance by using a plurality of flat filter plates next to one another, primarily in spans located in the shaping graduation plane. However, this requires a lot of effort in the production of these forms, increases the risk of filter breakage and leads to an uneven pouring flow rate.

The invention is therefore based on the object to design a filter so that a higher filtration performance, improved casting speed and easy installation in the casting system is achieved.

The present invention relates to a filter for the filtration of liquid metals according to claim 1. Advantageous embodiments are subject of the dependent claims or described below.

In particular, iron, steel, iron and steel alloys, but also non-ferrous metals such as aluminum, copper and / or alloys of these and other non-ferrous metals come into question as metals to be cast.

The filter according to the invention has a sleeve-shaped filter element which is surrounded by a filter housing. Apart from the inlet and outlet of the filter housing, the filter housing encloses the sleeve-shaped filter element, wherein the filter housing on the inlet side has a space for unfiltered and on the output side a space for filtered material. Upwards, d. H. into the filter housing in the direction of the inlet opening, the filter element is designed as a closed hollow dome. The hollow dome forms, in whole or in part, the space for filtered material on the exit side.

Outer and top (s) at z. B. cylindrical or tubular shape of the filter element or lateral surface in conical and dome-shaped shape form a closed filter surface. The usable filter surface is thus significantly increased compared to conventional flat filter elements in plate and disc shape.

Preferably, the lower opening of the filter element surrounds the outlet opening of the filter housing. The filter element is according to an embodiment thereof in the region of its opening to the outlet opening of the filter housing on the filter housing, z. B. in a groove which circulates the outlet used, or is inserted according to another embodiment in the outlet opening. Thus, according to one embodiment, the area of the opening of the filter element corresponds to the area of the outlet opening of the filter housing according to an embodiment, possibly apart from the material thickness of the filter element (relative to the sectional area parallel to the outlet). It is also possible that the outlet of the filter housing at its edge has a circumferential spring extending into the interior, which rotates the filter element at its opening edge on the inside.

Preferred material for the filter element is a foam ceramic. The filter element may also consist of another filter or Siebelementmaterial.

Foam ceramics and here in particular foamed-ceramic filter elements or partly also referred to as ceramic filters in foam structure are produced from a refractory material by means of a special production process, net-like structures of different porosity, in particular with a porosity of 5 to 80, in particular 10 to 65 ppi (pores per inch) , The porosity in ppi is optically determined by counting along any straight line sections on the surface of the filter and is an average.

As a basic element for the ceramic filter for this purpose, a plastic foam is used, on which the refractory materials are applied and solidified by special combustion processes. For this purpose, the starting material used is often corresponding plastic foams, which are dipped under deaeration in a ceramic slurry, a suspension of liquid and ceramic powders. If you take the plastic molding out of the slip again, remains due to the wetting of the foam slip on it. The molding is dried and then fired. During firing, the plastic is removed and the remaining ceramic replicates the molding. This results in an open-pored ceramic foam whose porosity is given in ppi (pures per inch). Reticulated plastics or plastic moldings are usually used as starting material. Reticulation destroys any thin "pellicles" created during production between the individual foam cells, which make the product impermeable to air.

Foam ceramic filters are used to remove slags and other impurities in the casting system and to calm the flow. Depending on the casting material, different filter materials and filter porosities are used. The foam ceramic filters are classified according to porosity classes (ppi). Refractory filter materials include those which have certain mechanical, thermal, chemical and functional properties. They must be chemically resistant to the deposited impurities and the melt, require a minimum strength and a good thermal shock resistance.

The number, size and type of filters are individually selected for each casting system and casting process. Typical foamed ceramics are z. Example of alumina, zirconia, silicon carbide, aluminum titanate, silicon nitride or aluminum nitride and mixtures thereof.

Preferred material for the filter housing is an inorganic bonded refractory material. The refractory material usable for the filter housings may consist of a refractory sand provided with a binder, suitably shaped and cured, commonly used in the steel and iron industry, or also of a special sand or special mineral. It may also be made from a refractory material filled into a lost or permanent mold. A refractory material is a refractory material, eg. B. metal oxides, prepared mixture, further comprising one or more corresponding binder, which harden in a subsequent drying and / or firing process to a solid and refractory article. For example, quartz, zirconium or chrome ore, olivine, chamotte and bauxite can be used as the refractory material. Furthermore, synthetically produced refractory materials can be used, such. B. aluminum silicate hollow spheres (so-called. Microspheres), glass beads, glass granules or the known under the name "Cerabeads" or "Carboaccucast" spherical ceramic mold base materials. Mixtures of said refractories are also possible. The refractory mold base materials are used in particular in the form of free-flowing powders.

The binder may, for. B. consist of a particulate metal oxide and water glass. Precipitated silica or fumed silica is preferably used as the particulate metal oxide. In another alternative, the binder contains an aqueous alkali silicate solution and a hygroscopic base, such as sodium hydroxide, in a ratio of 1: 4 to 1: 6. The water glass in particular has a modulus SiO ₂ / M ₂ O of 2.5 to 3.5. Other binders are synthetic resins, in particular polyurethane binders, and hydraulic binders.

The material for the filter housing may further consist of a dry- or wet-pressed, refractory material, which is brought into shape by the corresponding press dies and dried in a subsequent process and fired reaches its final strength.

But it can also consist of other materials which have the appropriate mechanical, thermal, chemical and functional properties for the application mentioned. These materials must be chemically resistant to the impurities and melts to be deposited at least for a while, require minimum strength and good thermal shock resistance.

Preferably, the filter element has a conical geometry for enlarging the outlet surface, so that its outer and / or inner circumference increases towards the outlet opening.

Filter housing lower and upper part can also have a different geometry (dome-shaped, bowl-shaped, cuboid, etc.) and have a different inlet and outlet configuration. For example, the inlet opening can also sit laterally in a bowl-shaped construction, the filters have two outlets with the second outlet on the circumference of the filter housing lower part, depending on the construction.

Filter housing lower and upper part and can also be designed so that the lower part has several receptacles for filter elements and the upper part is adjusted accordingly.

The lower part also has an equal number of outlets adapted to the number and shape of the filter elements. The inlets and outlets on the filter housing parts can also be attached laterally, depending on the meaningful geometry of the ceramic housing.

The invention will be further explained by the figures, without being limited thereto. Show it

1 an exploded view of a filter with two-part filter housing inserted in this cylindrical filter element,

2 a 3D cross-sectional view of a filter with a two-part filter housing with inserted in this filter element, and

3 a 2-D representation of the vertical section through the filter of 2 ,

filter element 1 is made of a refractory liquid metal permeable material and monolithic. It has a sleeve shape, ie one end of the substantially tubular hollow body is open, the opposite end 4 closed. From the open to the closed end 4 The body tapers conically in its interior. The opening of the filter element 1 serves as an outlet for the effluent filtered metal stream 12 ,

The outer surface of the filter element 1 can also be provided as a wave-shaped surface or with other geometric structures. The inner surface 5 As a metal flow exit surface is designed so that a maximum surface is reached, at the same time is the inner edge of the opening 9 of the filter element to the diameter of the outlet 13 adapted to the filter housing.

The lower part 2 of the filter housing has a customized recording 6 for the filter element 1 in the region of the opening of the filter element and thus serves as a holder and insert for the filter element 1 , At the same time, the filter housing lower part has an outlet opening 13 for the metal stream 12 and is made of z. As a commonly used for this purpose refractory material.

It can be between filter element 1 and the lower part 2 the filter housing a refractory seal and / or bonding 8th to a stable guide or holder of the filter element 1 in the lower part 2 find the filter housing use. The outlet 13 is with a spring 7 provided to ensure a straightforward adaptation to conventional casting systems with tongue and groove system. The lower part is connected 2 the filter housing via a groove or spring or other convenient connection 10 with the shell 3 of the filter housing.

The top 3 of the filter housing is similar to the lower part 2 carried out of the filter housing, namely of a usually used for this purpose refractory material and with a groove 14 adapted for common casting systems with tongue and groove system, which can be placed on the inlet opening. In 3 In this respect, the groove profile surrounding the inlet opening is shown for the tongue and groove system.

LIST OF REFERENCE NUMBERS

1

filter element

2

Filter Housing base

3

Filter housing top

4

Closed end of the filter element

5

Inner wall filter element

6

admission

7

groove

8th

sealant

9

Inner edge of the opening of the filter element

10

Tongue and groove connection Filter housing lower and upper part

11

Incoming metal stream

12

Leaking metal stream

13

Outlet opening of the filter housing lower part

14

Groove in the inlet opening of the filter housing upper part

15

Inlet opening of the filter housing

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 3902151 A1 [0002]
• DE 422917 C2 [0003]

Claims (13)

Having filters A filter housing made of refractory material with at least one inlet opening and at least one outlet opening and • at least one filter element arranged in the filter housing for filtering liquid metal, wherein The filter element is surrounded by the filter housing, The filter element is in the form of a hollow sleeve with an opening, and The opening of the filter element extends to or forms the outlet opening of the filter housing. A filter according to claim 1, wherein the sleeve is in the form of a hollow cylinder or a hollow truncated cone. Filter according to at least one of the preceding claims, wherein the filter housing is formed in two parts as a filter housing lower part and filter housing upper part and the filter housing lower part receives the outlet opening and the filter element. Filter according to claim 3, wherein filter housing lower part and the filter housing upper part with a tongue-and-groove system engage interlocking. Filter according to claim 3 or 4, wherein the filter housing lower part and the filter housing upper part increase from its inlet opening or outlet opening in the direction of the respective other housing part in the periphery. Filter according to at least one of the preceding claims, wherein the surface of the outlet of the filter housing and the surface of the opening of the filter element substantially correspond. Filter according to at least one of the preceding claims, characterized in that the filter element is inserted in the region of its opening in the outlet region of the filter housing and optionally provided with a sealing compound in the region of the contact surface. Filter according to at least one of the preceding claims, wherein the filter element and the filter housing or filter housing lower part engage with a tongue and groove system. Filter according to at least one of the preceding claims, wherein the inlet opening of the filter housing upper part is equipped with a part of a tongue and groove system for connecting a casting element with the other part of the tongue and groove system. Filter according to at least one of the preceding claims, wherein the filter element consists of a foam ceramic. Filter according to at least one of the preceding claims, wherein the inner radius of the sleeve at least partially decreases away from the opening of the filter element. Filter according to at least one of the preceding claims, wherein in the case of multiple outlet openings in the same number filter elements are given, wherein in each case an outlet opening and a filter element correspond with each other. Filter according to at least one of the preceding claims, wherein the sleeve has a substantially uniform wall thickness, possibly apart from areas where the sleeve forms corner regions.

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