JP2502995B2 - Fluid permeable glass product and manufacturing method thereof - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to a fluid-permeable glass product and a method for producing the same, and more particularly to a novel glass product having continuous pores and fluid-permeable properties, and such a glass product. The present invention relates to a method for producing the above, advantageously without adding mechanical processing.

(Background Art) Conventionally, glass products having various shapes such as glass bottles, glass tubes, and plate glasses have been manufactured, and are widely used for various purposes such as household use and industrial use.

By the way, in such a glass product, it is extremely easy to form a hollow tubular body (pipe) or hollow body by blow molding or draw molding. For example, a glass product which is provided with three-dimensionally continuous fine pores such as that set in a metal produced by a sintering method and is provided with a property of allowing a fluid such as a gas or a liquid to pass therethrough, and the production thereof. The law has not yet been provided.

(Structure of the Invention) Here, the present invention has been made in view of the above circumstances, and an object of the present invention is to provide a novel porosity that has continuous pores and has a property of allowing a fluid to pass therethrough. It is an object of the present invention to provide a glass product and a method for advantageously manufacturing such a glass product without adding mechanical processing or the like.

In order to achieve such an object, the gist of the present invention is that a porous structure having continuous pores formed between and / or within a skeleton as a whole is made of a predetermined glass material. The porous structure is integrally embedded and retained in the molded product, and at least a part of the porous structure is exposed or communicated with the product surface, and the pores of the site are opened or connected to the outside. It is a fluid permeable glass product characterized by having a structure.

In the present invention, preferably, the porous structure is a flammable structure capable of producing continuous pores through which a fluid can pass by burning, for example, a resin foam from which a foam film is removed, a resin A predetermined ceramic material is adhered around a skeleton such as a comb-shaped body or a sword-shaped product, and it is obtained by burning the combustible portion constituting the skeleton portion by firing and sintering the ceramic material. While a predetermined skeleton structure is retained by the sintered body of the adhered ceramic material, the inside of the skeleton is hollow, a porous ceramic body in which continuous pores are formed through which a fluid can pass, Further, the glass material enters the skeleton gap of the ceramic porous body to form a matrix for the ceramic porous body.

In addition, in the present invention, in order to advantageously obtain such a fluid-permeable glass product, a melt of a predetermined glass material is supplied into a molding cavity of a predetermined molding die to obtain a molded product of a desired shape. When forming, a flammable structure capable of creating continuous pores through which the fluid can pass by burning, such as a resin foam from which the foam film has been removed, a resin comb-like body, or a skeleton of a sword-shaped product, etc. A predetermined skeleton is obtained by a sintered body of the adhered ceramic material obtained by attaching a predetermined ceramic material to the While the structure is retained, the inside of such a skeleton is hollow, and a porous ceramic body in which continuous pores are formed as a whole through which a fluid can pass is used. In a state where the glass material is placed at a predetermined position in the cavity, the melt of the glass material is supplied, and the supplied melt is allowed to enter the skeletal structure of the ceramic porous body to be integrated with the surrounding melt. The method for producing a fluid permeable glass product, which comprises forming a molded product in which the porous ceramic body is integrally embedded at a predetermined position by solidifying the ceramic porous body, is suitably adopted.

(Specific Description of Configuration) More specifically, the present invention is, for example, as shown in FIG. 1, a porous structure at a predetermined position in a mold (molding die), as shown in FIG. As shown in FIGS. 3 to 5, by supplying and filling a melt by heating a predetermined glass material in a state in which a ceramic porous body having a specific structure as shown in FIG. An object of the present invention is to manufacture a glass product having three-dimensionally continuous pores (pores) and having a property of allowing a fluid to pass therethrough.

By the way, FIG. 1 shows an example of the production of the product of the present invention by a casting method, in which 10 is a mold, and a molding cavity 20 having a predetermined shape is formed in the mold 10. There is. The ceramic porous body 22 having a predetermined three-dimensional mesh structure is set in the cavity 20 as a porous structure. In addition, a predetermined mold release agent is applied to the inner surface of the cavity 20 of the mold 10 as necessary, avoiding sticking of the melt 26 of the glass material to be injected, and thus, after solidification thereof, The molded product can be easily taken out of the mold 10.

In FIG. 1, the ceramic porous body 22 is placed on the bottom of the molding cavity 20 in order to obtain a product in which the porous ceramic body is embedded while being exposed only on one surface of the glass product. Although set, the arrangement position and shape of the ceramic porous body in the glass product are not limited, and are determined according to the intended product. Molding cavity 20
When setting in a state of floating from the inner surface, an appropriate stopper such as a pin will be used appropriately.

Here, the ceramic porous body 22 having a three-dimensional network structure as the porous structure according to the present invention, which is arranged and fixed in the cavity 20, is formed by foaming a resin such as ester urethane and then surrounding the skeleton thereof. The synthetic resin foam having a skeleton structure with a three-dimensional network structure obtained by removing the film-like substance (foamed film) remaining on the skeleton using compressed air etc. It is obtained by adhering the above ceramic material, drying, and baking. As a ceramic material to be attached to such a synthetic resin foam, cordierite, alumina, SiC, mullite, zirconia, etc. are appropriately selected and adopted according to the characteristics required for the intended product. It is what is done.

When manufacturing such a ceramic porous body, for example, the thermal decomposition temperature of the urethane resin used as a synthetic resin foam is about 400 ° C., while the firing temperature of the ceramic material attached to the surface of the skeleton is usually 1300
Since the temperature is not lower than 0 ° C, the urethane resin can be decomposed and disappeared almost completely by adhering the ceramic material on the skeleton side and baking it for about 24 hours.

Therefore, in the ceramic porous body 22 used in the present invention as the porous structure obtained by such a method, as shown in FIG. 2, a skeleton 34 having a three-dimensional network structure is formed. In addition, the skeleton 34 itself is hollow, and pores 36 that are continuous as a whole are formed in the skeleton 34. The ceramic porous body 22 having such a structure generally has a porosity of about 60 to 90% and varies depending on the number of cells, but as the length of one side of the skeleton constituting the cell, for example, 0.1 to It is about 0.4 mm.

And, a ceramic porous body having such a structure
With the 22 placed in the cavity 20, a melt 26 of a glass material selected depending on the physical properties required for the glass product is poured.

Thus, the molten glass material 26 to be poured is generally introduced into the molding cavity 20 after being sufficiently melted by heating or the like, as shown in FIG.
While filling the gap between the skeletons 34 of the three-dimensional network structure of the ceramic porous body 22, it reaches the upper surface of the ceramic porous body 22,
Thereby, the degree of filling the gap between the porous ceramic bodies 22 can be known.

As the glass material 26, when it is melted by heating, the molding cavity 20
When introduced into the mold, a temperature drop due to contact with the inner wall surface of the mold 10 is unavoidable, and the installation of the ceramic porous body 22 further promotes this tendency.
The material temperature at the time of pouring is preferably set higher than a normal temperature, or the mold 10 and the like are heated by an appropriate heating means.

In addition, the glass material 26 is replaced with the ceramic porous body 22.
It is desirable to apply an appropriate injection pressure in order to uniformly infiltrate between the skeletal tissues (in the cell) and to fill and solidify. In this sense, in addition to the casting method as described above, a pressure molding method in which an appropriate molding pressure is applied to the molten glass material is preferably adopted in the present invention.
In this pressure molding method, so-called insert molding is performed in which the pressure molding operation is performed under the condition that the ceramic porous body is set in the molding cavity in the molding die.

The glass product 32 thus solidified by solidification is composed of a skeleton 34 having a three-dimensional network structure of the porous ceramic body 22 as shown in FIGS. 3 and 4. While the glass material 40 enters the cell to be formed, and the glass material 40 forms an integral structure in which the glass material 40 constitutes a matrix for the ceramic porous body 22, the inside of the skeleton 34 of the embedded ceramic porous body 22 is formed. The penetration of the molten glass material 26 into the holes 36 is
Since it is blocked by the surface tension, the holes 36
Will be held in communication.

In addition, such glass products undergo the usual finishing process after solidification by solidification is completed,
In particular, in the glass product of the present invention, the openings of the pores 36 in the exposed surface 38 of the skeleton 34 of the ceramic porous body 22 embedded therein are solidified glass materials 40. Since the exposed surface 38 is closed by the cutting process and the polishing process, the holes 36 are opened to the outside, and as a result, FIG. As shown in FIG. 5, a desired glass product 32 having a characteristic that a fluid can permeate is obtained by providing fine continuous pores (pores) having a three-dimensional network structure inside. .

In FIGS. 3 and 4, the glass material 32 according to the present invention is shown in a two-dimensional cross section, and therefore the glass material 40 is shown in a divided form. Body 22 is a three-dimensional network skeleton 34
It is to be understood that the cell structure has a continuous cell formed inside, and thus has a three-dimensionally continuous and integrated structure. Is.

Although the fluid permeable glass product having the structure according to the present invention has been described in detail above, the present invention is not construed as being limited to the description of the specific configuration, and particularly its use. However, it should be understood that it can be adopted in a very wide range.

For example, by using the fluid permeable glass product according to the present invention, it is possible to reach the inside of the ceramic porous body and connect it to the pores of the site, the inflow part and the outflow part are provided, and the embedded ceramic porous body is provided. It is also possible to form a cooling or heating member by circulating a cooling fluid or a heating fluid in the pores, and by using such pores, it is possible to use it as a filter member or a catalyst. Is.

Further, in the illustrated specific example, a ceramic porous body having a hollow skeleton structure of a three-dimensional network structure is given as a suitable example of the porous structure. Any porous structure can be used as long as the pores are formed between and / or within the skeleton. For example, a porous sintered material can be used. The body is a combustible structure, such as a ceramic porous body, which can generate continuous pores through which a fluid can pass when burned out, for example, a resin foam (an example) from which a foam film is removed, a resin-made body made of resin. A predetermined ceramic material is adhered around a skeleton such as a comb-shaped body or a sword-shaped product, and it is obtained by burning the combustible portion constituting the skeleton portion by firing and sintering the ceramic material. Adherence A ceramic porous body in which a predetermined skeleton structure is held by a sintered body of a ceramics material, while the inside of the skeleton is hollow, and continuous pores are formed as a whole through which a fluid can pass. Preferably, particularly by using such a ceramic porous body,
The integration with the glass material can be effectively performed, and the desired fluid-permeable glass product can be advantageously obtained.

In addition, although not enumerated one by one, the present invention can be carried out in a mode in which various changes, modifications, improvements and the like are added based on the knowledge of those skilled in the art, and such an embodiment has the gist of the present invention. It goes without saying that all of them are included in the scope of the present invention without departing from them.

(Effects of the Invention) The glass product according to the present invention as described above is provided with fine continuous pores having a porous structure such as a three-dimensional network structure, and has a property of allowing fluid to pass therethrough. However, glass products with such characteristics have not been found in the past, and fluids such as air, gas, water, hot water or oil can be freely placed in these holes (pores) depending on the intended use of the glass product. In addition to being used for a fluid supply body, a blowing body, a diffusion stirrer by a gas jet, etc. It can be suitably used as a stretcher (support) in the field of biotechnology that uses the inner surface of continuous pores, and brings a new development to the design work of glass products over an extremely wide range. .

Further, in the present invention, by producing a fluid-permeable molded article using glass, the resulting molded article has a light-transmitting property, and since it can be colored, it may be color-coded according to its use. Moreover, since such a molded product is molded by a mold, it can be advantageously manufactured with a small processing rate.

[Brief description of drawings]

FIG. 1 is a cross-sectional explanatory view showing one step of the method for producing a glass product according to the present invention, and FIG. 2 is an enlarged cross-sectional explanatory view of a main part showing a ceramic porous body used therein.
FIG. 3 is an enlarged cross-sectional explanatory view of an essential part showing a glass product obtained by such a manufacturing method, FIG. 4 is an enlarged view of the glass product in FIG. 3, and FIG. 5 is the entire glass product. It is a perspective view. 10: Mold, 20: Mold cavity 22: Porous ceramics 26: Melt of glass material 34: Skeleton, 36: Hole 40: Glass material

Claims (3)

(57) [Claims] 1. A porous structure having continuous pores formed between skeletons and / or within a skeleton is integrally embedded and held in a molded article made of a predetermined glass material, and At least a part of the porous structure is exposed to or communicated with the product surface, and the pores of the part are structured to have an opening or connection to the outside. . 2. The combustible structure, wherein the porous structure can generate continuous pores through which a fluid can pass when burned out, for example, a resin foam from which a foam film is removed, a resin comb-shaped body, or Kenzan. A predetermined ceramic material is adhered around the skeleton of a shaped product, and is burned and sintered to burn out the combustible portion constituting the skeleton, and the obtained ceramic material is burned. A ceramic porous body in which a predetermined skeleton structure is held by a binding body, and the inside of the skeleton is hollow, and continuous pores are formed as a whole through which a fluid can pass, and the porous ceramic body The glass material enters the skeletal gap of
The fluid permeable glass product according to claim 1, which constitutes a matrix for the ceramic porous body. 3. When a molten material of a predetermined glass material is supplied into a molding cavity of a predetermined molding die to form a molded product of a desired shape, continuous pores through which fluid can pass by burning are formed. Combustible structures that can be produced, for example, resin foam from which the foam film has been removed, resin-like combs, sword-like products, and other skeletons are adhered with a predetermined ceramic material and then sintered and sintered. By squeezing, a predetermined skeletal structure is retained by the sintered body of the adhered ceramic material, which is obtained by burning out the combustible portion forming the skeletal portion, while the inside of the skeleton is hollow, A porous ceramic body in which continuous pores are formed as a whole through which a fluid can pass is used, and the porous ceramic body is placed at a predetermined position in the molding cavity. The molten ceramic material is supplied to the skeletal structure of the ceramic porous body and solidified together with the surrounding molten material so that the ceramic porous body is positioned at a predetermined position. A method for producing a fluid-permeable glass product, characterized in that the molded product is integrally embedded in the molded product.