Ceramic Filter And Manufacturing Method Therefor

Abstract

In order to enable stable provision of an upward release tube-type ceramic filter used in a molten metal bath and having a side wall with a height of 300 mm or greater, this method for manufacturing a ceramic filter, which is an upward release tube-type integrally molded article for removing unwanted substances from molten metal, has: a step for kneading a mixture of an aggregate comprising ceramic particles, a prescribed binding agent, and water to prepare a base material; a step for integrally forming an upward release tube-type ceramic filter precursor from the prepared base material; step for drying the precursor; a step for providing a retainer for the dried precursor for supporting a side wall of the precursor; a step for subsequently sintering the precursor; and a step for removing the retainer after sintering.

Claims

1. A method for manufacturing an integrally-formed open-topped tubular ceramic filter for removing contaminant from molten metal, the method comprising the steps of: kneading an aggregate comprising ceramic particles, a predetermined binding agent, and water to prepare a mixture; integrally forming a precursor of an open-topped tubular ceramic filter from the prepared mixture; drying the precursor; setting up a retainer for the dried precursor to support a side wall of the precursor; subsequently sintering the precursor; and removing the retainer after sintering.

2. The manufacturing method according to claim 1, further comprising, before the sintering step and after the drying step, the step of coating the side wall of the precursor with a layer made of a material that is stable against the molten metal and an oxide thereof and that has a sintering temperature lower than a sintering temperature of the precursor.

3. A method for manufacturing an integrally-formed open-topped tubular ceramic filter for removing contaminant from molten metal, the method comprising the steps of: kneading a mixture of an aggregate comprising ceramic particles, a predetermined binding agent, and water to prepare dough; integrally forming a precursor of an open-topped tubular ceramic filter from the prepared dough; drying the precursor; coating an upper edge of a side wall of the dried precursor with a layer made of a material that is stable against the molten metal and an oxide thereof and that has a sintering temperature lower than a sintering temperature of the dough of the precursor; and subsequently sintering the precursor.

4. An integrally-formed open-topped tubular ceramic filter comprising a sintered body of ceramic particles capable of allowing molten metal to pass therethrough, the ceramic filter having a bottom wall and a side wall vertically extending from the bottom wall so as to have a height of 500 mm or more.

5. The ceramic filter according to claim 4, wherein an upper edge of an opening provided at a top of the ceramic filter is coated with a protective film made of a material that is stable against the molten metal and an oxide thereof and that has a sintering temperature lower than a sintering temperature of the ceramic particles.

6. A method for manufacturing an integrally-formed open-topped tubular ceramic filter for removing contaminant from molten metal, the method comprising the steps of: kneading an aggregate comprising ceramic particles, a predetermined binding agent, and water to prepare a mixture; integrally forming a precursor of an open-topped tubular ceramic filter from the prepared mixture; drying the precursor; and subsequently sintering the precursor, wherein in the step of integrally forming a precursor, the mixture is filled into a space between an outer mold and an inner mold, and in the drying step, the precursor is warmed together with the inner mold to thermally shrink the inner mold.

7. The manufacturing method according to claim 6, wherein the inner mold is made of a foamed resin material, and a surface thereof is coated.

8. The manufacturing method according to claim 7, wherein the surface of the inner mold made of a foamed resin material is coated with a heat-shrinkable resin tape.

9. The manufacturing method according to claim 6, wherein in the sintering step, a side wall of the precursor is supported by another member.

Description

BRIEF DESCRIPTION OF DRAWINGS

[0027] FIG. 1 is a sectional view of a forming mold of a precursor used in an embodiment of the present invention.

[0028] FIG. 2 is a perspective view of the precursor.

[0029] FIG. 3 is a sectional view of the precursor having a protective film.

[0030] FIG. 4 is a sectional view showing a retainer supporting the precursor during sintering.

[0031] FIG. 5 is a sectional view of a modified embodiment of the precursor during sintering.

[0032] FIG. 6 is a schematic view showing the structure of a side wall of a modified embodiment of the precursor.

DESCRIPTION OF EMBODIMENT

[0033] Dough of a precursor contains an aggregate including ceramic particles, a predetermined binding agent, and water.

[0034] The aggregate are used in any ratio with regard to the dough and, for example, comprises one or more materials selected from the group consisting of silicon carbide, silicon nitride, boron nitride, zirconium oxide (zirconia), aluminum oxide (alumina), and zircon.

[0035] The particle diameter of the aggregate may freely be selected according to characteristics required of a ceramic filter, but is preferably 0.01 mm to 10 mm, more preferably 3 mm to 6 mm. The particle diameter can be determined by common sieves.

[0036] As the binder, an organic binding agent, inorganic cement, and powdered glass may be used.

[0037] The organic binding agent binds the aggregate before sintering to retain the shape thereof.

[0038] As such an organic binding agent, a water-soluble and viscosity improving agent such as polyvinyl alcohol or starch may be used.

[0039] The viscosity improving agent is burnt off by sintering, and therefore inorganic cement is used to bind the aggregate during sintering. As the inorganic cement, silica-free inorganic cement (alumina cement) is preferably used. This is because that the inorganic cement does not react with molten metal, especially with an oxide thereof.

[0040] The powdered glass is vitrified by sintering and finally binds the aggregate. The powdered glass shall have a vitrification temperature (melting point) sufficiently higher than the temperature of molten metal.

[0041] These binding agents are dissolved or dispersed in a predetermined amount of water and mixed with the aggregate. The amount of the organic binding agent is preferably 0.1 to 0.5 mass % with respect to the total mass of the aggregate and the binder. The amount of the inorganic cement is preferably 0.5 to 10 mass %. The amount of the powdered glass is preferably 0.5 to 10 mass %.

[0042] The amount of water is appropriately adjusted so that a mixture having a desired viscosity is obtained.

[0043] The thus obtained mixture has almost no fluidity. Such a mixture is filled into a mold to integrally form a precursor of a ceramic filter.

[0044] FIG. 1 illustrates a mold 10 for forming a precursor 1.

[0045] The mold 10 includes an outer mold 11 and an inner mold 13. Reference sign 15 denotes a base. The outer mold 11 is a plate-shaped member and may be made of metal or ceramic. On the cavity surface of the outer mold 11, a releasing agent is applied to easily demold the precursor 1.

[0046] As the inner mold 13, a foamed resin is used. A protective film also made of a resin is laminated on the cavity surface of the inner mold 13 to prevent permeation of the mixture. As the protective film, a heat-shrinkable tape or a coating material may be used. On the surface of the protective film, a releasing agent is applied to easily demold the precursor 1.

[0047] In the present invention, the precursor 1 is dried before demolding, that is, the precursor 1 is dried with at least the inner mold being left.

[0048] The precursor 1 is dried under general conditions of 80° C. to 100° C. for 5 hours to 15 hours. Under such conditions, the foamed resin material thermally shrinks. Therefore, demolding is easily performed even when the precursor 1 has a high side wall.

[0049] The shrinkage coefficient of thermal shrinkage of the foamed resin material may be about 1 to 10% as long as the dried precursor 1 can be demolded from the inner mold. Another material having a similar shrinkage coefficient may be used instead of the foamed resin material.

[0050] The whole of the precursor 1 after demolding is shown in FIG. 2. The precursor 1 has a vertical side wall 3 having a height of 500 mm or more. The thickness of the side wall 3 may freely be selected according to characteristics required of a ceramic filter, but is 20 to 35 mm. A bottom wall 5 has the same thickness (see FIG. 3).

[0051] The upper edge of the side wall 3 of the precursor 1 is coated with a protective film 7. The coating is performed by application or spraying.

[0052] As has been described above, the protective film 7 is made of a material that is stable against molten metal and an oxide thereof and that has a sintering temperature lower than that of the dough of the precursor. An area coated with the protective film 7 may freely be set, but is preferably set so that margins of 100 mm or more are provided above and below the upper surface level of molten metal. Further, the upper edge of the side wall is preferably coated entirely from the viewpoint of ease for application and impartment of strength.

[0053] The protective film 7 is vitrified before the dough of the precursor 1, that is, before the powdered glass during sintering of the precursor 1.

[0054] The precursor 1 having the protective film 7 is placed in a sintering furnace. At this time, a retainer 20 is set up to prevent the collapse of the side wall 3 (FIG. 4). The retainer 20 includes a first retainer 21 configured to support the side wall 3 from the outside and a second retainer 23 configured to support the side wall 3 from the inside.

[0055] The first retainer 21 supports the entire outer surface of the side wall 3. The first retainer 21 is preferably in close contact with the outer surface of the side wall 3. The side wall tends to deform due to expansion during sintering, and therefore the first retainer 21 preferably faces the entire outer surface of the side wall.

[0056] The second retainer 23 prevents the side wall from deforming inward. The side wall deforming outward causes to contact the first retainer 21 so that it may rebound inward. The second retainer 23 prevent such the rebounding. The second retainer does not need to face the entire inner surface of the side wall. In this example, the second retainer is provided on the upper edge side of the side wall to support the inner surface of the side wall. The second retainer may intermittently support the inner surface of the side wall. In this example, L-shaped ceramic plates (width: 100 mm) as the second retainer 23 are arranged as closely as possible so as to be fitted to the upper edges of the precursor 1 and the first retainer 21.

[0057] When such a retainer 20 is used, the protective film 7 may be omitted.

[0058] On the other hand, when the protective film 7 is widely formed (in a vertical direction), the second retainer 23 or the retainer 20 as a set of the retainers may be omitted.

[0059] FIG. 5 illustrates, as an example, a precursor 31 having a side wall 33 inclined outward. In the case of such a precursor 31, the side wall 33 can be supported only by a first retainer 42 facing the outer surface of the side wall 33 to prevent the deformation of the side wall 33 during sintering.

[0060] The deformation of side wall of the precursor during sintering is caused also by self-weight when the side wall has a height as high as more than 300 mm. However, the side wall cannot be made thicker than a certain thickness because the thickness of the side wall is limited in terms of the ability to allow molten metal to pass through. Therefore, as shown in FIG. 6(a), a side wall 53 may be bent to enhance rigidity in a vertical direction. Alternatively, as shown in FIG. 6(b), ribs 67 may be provided in a side wall 63 so as to be continuous in a vertical direction.

Examples

[0061] Hereinbelow, an example of the present invention will be described.

[0062] First, the following mixture was obtained. The following mixing ratio is expressed in parts by mass.

[0063] Aggregate 1 (silicon carbide, particle diameter: 3 to 6 mm): 70 parts by mass

[0064] Aggregate 2 (silicon carbide, maximum particle diameter: 8 mm): 30 parts by mass

[0065] Organic binding agent (polyvinyl acetate, model number: ISOBAN-110 manufactured by Kuraray Co., Ltd.): 0.6 parts by mass

[0066] Inorganic cement (alumina cement, model number: High Alumina Cement Super S manufactured by Denka Company Limited): 5 parts by mass

[0067] Powdered glass (fritted glass, model number: 4791 manufactured by Nippon Horo Yuyaku Co., Ltd.): 5.5 parts by mass

[0068] Water (Tap water): 3.8 parts by mass

[0069] A mixture of them was kneaded by a universal mixing stirrer (manufactured by Sankei Seisakusho K.K.).

[0070] An outer mold 11 and an inner mold 13 were set up to prepare a mold 10 of a precursor 1. The precursor 1 has an open-topped box shape having a height of 500 mm, a width of 500 mm, and a length of 700 mm. A side wall 3 and a bottom wall 5 have a thickness of 25 mm. The outer mold 11 was made entirely of an iron plate. The inner mold 13 was made of expanded polystyrene (EPS: expansion ratio 90), and a tape (PYOLAN CLOTH ADHESIVE TAPE manufactured by Nitoms, Inc.) was adhered to the entire surface of the inner mold 13. Vaseline (manufactured by Chukyo Yushi Co., Ltd.) was applied as a releasing agent onto the cavity-forming surfaces of the outer mold 11 and the inner mold 13.

[0071] The kneaded mixture was filled into the cavity of the mold 10 and dried in a general-purpose drying furnace under conditions of 80° C. for 15 hours without removing the mold 10. As a result, the inner mold 13 shrank and therefore could easily be removed.

[0072] A protective film 7 was applied onto the upper edge of side wall of the dried precursor 1. The material of the protective film 7 was obtained by dispersing particles of zirconia in a binder. The zirconia used here was G325F (product number) manufactured by Fukushima Steel Works Co., Ltd. The binder used was ALKONPATCH PT85U (product name) manufactured by Calderys Japan Co., Ltd. The mixing ratio between the zirconia and the binder was 3:7 (mass ratio). The thickness of the protective film 7 applied was 1 to 2 mm as measured by eye.

[0073] The protective film 7 was dried, and then the precursor 1 was placed in a sintering furnace. At this time, a retainer 20 was set up as shown in FIG. 4. As a first retainer 21, fire-proof bricks were used. The first retainer 21 was set up so as to be in close contact with the outer surface of the side wall 3. A second retainer 23 was set so as to cover the first retainer 21 and the side wall 3 without being forcedly fitted to them.

[0074] Then, the precursor 1 was sintered at a maximum temperature of 1100° C. for 27 hours. Conditions for temperature rise to the maximum temperature and conditions for cooling after sintering are not particularly limited, and may be those generally used.

[0075] The thus obtained ceramic filter retained the shape of the precursor. The ceramic filter could be used in an aluminum molten metal bath. The ceramic filter of this example was superior in durability to a conventional ceramic filter formed by combining flat plates.

[0076] The present invention is not limited to the above description of the embodiment according to the present invention and modified examples thereof. Various modified embodiments are also included in the present invention as long as they are easily conceivable by those skilled in the art and do not depart from the scope of the claims.

REFERENCE SIGNS LIST

[0077] 1 Precursor [0078] 3, 33, 53, 63 Side wall [0079] 7 Protective film [0080] 10 Mold [0081] 11 Outer mold [0082] 13 Inner mold [0083] 20 Retainer [0084] 21, 42 First retainer [0085] 23 Second retainer