JPH0615148A - Sealing structure of filter and ceramic membrane filter - Google Patents

Abstract

PURPOSE:To enable the easy removal of a ceramic membrane filter out of a permeation device without the failure thereof and the assembly thereof into the device by sealing both end faces of the ceramic membrane filter with coating films and providing annular moldings made of a thermoplastic resin so as to cover the edges of the end faces thereof. CONSTITUTION:Both end faces in the longitudinal direction of the ceramic membrane filter 1 formed to a circular columnar shape, etc., at the outer contours are sealed with the coating films 2. The annular moldings 3 made of the thermoplastic resin are further fixed to both ends in the longitudinal direction of the ceramic membrane filter 1. The annular molding 3 on one end side of the ceramic membrane filter 1 is inserted and fixed into the recessed part 6d of a first cap 6 at the time of mounting the ceramic film filter 1. A first, sealing member 4A is fixed to the spacing between the flange 6b of the cap 6 and the annular molding 3 and the other end thereof is formed similarly. The ceramic membrane filter is thus easily mounted and removed and the edges 1c thereof are coated and protected.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a filter having a ceramic membrane filter and a seal structure.

[0002]

2. Description of the Related Art It has been strongly pointed out that tap water has become unusable for several years. The causes are chlorine, rust, chlorine odor, bacteria and the like. Furthermore, it has recently been pointed out that the carcinogen trihalomethane is present in tap water. Under these circumstances, household water purifiers that remove harmful substances to the human body are attracting attention. Many of the currently known water purifiers use a combination of activated carbon and a hollow fiber membrane filter, and remove rust and bacteria that cannot be removed by activated carbon by the microfiltration function of the hollow fiber membrane. An example thereof is that disclosed in Japanese Patent Laid-Open No. 2-198684.

However, the water purifier using the above hollow fiber membrane filter has the following problems. Since the hollow fiber membrane also becomes clogged with time, it is necessary to regularly remove the clogging in order to maintain the filter function. In order to remove the clogging, it is conceivable to carry out chemical cleaning or to remove the organic matter causing the clogging by incineration. However, since the hollow fiber membrane is a plastic organic membrane and has poor chemical resistance and heat resistance,
Such a system cannot be adopted at all. Therefore, it is conceivable to pass the washing water, but in this case, a pressure higher than that during the filtration action is applied. When such a high pressure is applied to the hollow fiber membrane, which is an organic membrane, the pores of the membrane widen and the filter function is impaired. This point is the same even when the method of washing by applying a reverse pressure to the filter is adopted.

After all, although the hollow fiber membrane filter has a high purification function, it cannot be reused when it is clogged and must be discarded, and the maintenance cost of the water purifier is high. In particular, considering that the filter is used in general households, the hollow fiber membrane filter is unsuitable because of high maintenance cost.

[0005]

In order to solve these problems, the present applicant has proposed a water purifier having a ceramic membrane filter in Japanese Patent Application No. 4-10166. However, in the process of further study, it became clear that there is no suitable method for sealing the ceramic membrane filter. That is, the outer contour of the ceramic membrane filter has, for example, a cylindrical shape, and the water passage is provided from one end to the other end. In order to prevent the raw water and the filtered purified water from being mixed, both ends of the ceramic membrane filter must be waterproofed and sealed.

Japanese Unexamined Patent Publication (Kokai) No. 64-51108 discloses that a cylindrical filter made of ceramics is sealed at its end face, and a pair of two kinds of support plates are combined with an O-ring to support the cylindrical filter and seal it. A method of doing so is disclosed. In addition, there is a so-called crimping method. This will be described with reference to the schematic sectional view of FIG. A protrusion 11a is formed on the side peripheral surface of the case body 11, and a purified water outlet 16 is provided inside the protrusion 11a. A protrusion 12a is formed near the center of the lid 12, and a raw water supply port 15 is provided inside the protrusion 12a. An annular packing 17A is sandwiched between the case body 11 and the lid 12. For example, the case body 11 and the lid 12 are coupled to each other by a pair of bolts 13 and nuts 14. Packing 17C is the case
11, the one end of the ceramic membrane filter 1 contacts the packing 17C, the other end of the filter 1 contacts the packing 17B, and the packing 17B contacts the lid 12.
The through hole 18 of the packing 17B and the raw water supply port 15 communicate with each other. By tightening the nut 14, pressure is applied in the length direction of the ceramic membrane filter 1 to seal it. When the raw water is supplied from the raw water supply port 15 as shown by the arrow C, the filtered purified water leaks from the side peripheral surface of the filter 1 as shown by the arrow D. This purified water is discharged from the purified water outlet 16 as shown by arrow E.

However, in any of the above-mentioned sealing methods, many parts are required for sealing and fixing the ceramic membrane filter 1, and it is very troublesome when taking out or incorporating the ceramic membrane filter from the filter. It was hanging. Further, a force may be applied to both end faces of the ceramic membrane filter 1, and in particular, the edge portions thereof may be chipped.

[0008] An object of the present invention is to provide a filter and a sealing structure which allows the ceramic membrane filter to be easily taken out of the filtration device or incorporated therein. It is also intended to prevent damage to the vicinity of both end faces of the ceramic membrane filter, especially the edge portions thereof.

[0009]

SUMMARY OF THE INVENTION The present invention is directed to a ceramic membrane filter having a columnar outer contour, a coating film for plugging both lengthwise end faces of the ceramic membrane filter, and at least the end face. The present invention relates to a filter provided with an annular molded body made of a thermoplastic resin, which is fixed to both ends of the ceramic membrane filter so as to cover the edge.

Further, according to the present invention, a ceramic membrane filter having a columnar outer contour, a coating film for sealing both end faces in the length direction of the ceramic membrane filter, and at least an edge of the end face are covered. A thermoplastic resin annular molded body that is respectively fixed to both ends of the ceramic membrane filter, and fitted and fixed to the annular molded body on one end side of the ceramic membrane filter, the raw water A first cap having a supply port, a first sealing member fixed in a gap between the first cap and the annular molded body, and the annular molded body on the other end side of the ceramic membrane filter. A ceramic membrane fill provided with a second cap fitted and fixed with respect to the second cap, and a second seal member fixed in a gap between the second cap and the annular molded body. Those of the seal structure over.

[0011]

DESCRIPTION OF THE PREFERRED EMBODIMENTS FIG. 1 (a) is a partial cross-sectional view showing a filter according to an embodiment of the present invention, and FIG. 1 (b) is an enlarged view of a main part of FIG. 1 (a). FIG. 2 is a partial cross-sectional view showing the seal structure according to the embodiment of the present invention. The outer contour of the ceramic membrane filter 1 in this embodiment is cylindrical. A large number of water passage holes are provided inside the ceramic membrane filter 1, each water passage hole extends in the length direction of the filter 1, and is open at both end faces 1 a in the length direction of the filter 1. The entire ceramic membrane filter 1 is made of a relatively large particle ceramic carrier. A ceramic intermediate membrane having a smaller pore diameter and a ceramic fine pore membrane having a smaller pore diameter are provided on the peripheral wall of each water passage hole. At this time, a ceramic intermediate film is provided between the ceramic pore film and the ceramic carrier so that the ceramic pore film surrounds the water passage hole and is exposed.

A coating film 2 is formed on each end surface 1a of the filter 1 in the length direction except the water passage holes.
Each end face 1a is plugged with the coating film 2. Examples of this material include glazes, inorganic materials such as alumina-based ceramic bonds, suspensions of silicon resin and fluororesin, and organic materials such as epoxy resins.

An annular molded body 3 is fixed to both ends of the ceramic membrane filter 1 in the lengthwise direction. The annular molded body 3 is made of a thermoplastic resin described later. In the present embodiment, the relatively thick base portion 3a covers the end portion of the side peripheral surface 1b of the filter 1, and the protruding portion 3b thinner than the base portion 3a covers the edge 1c of the end surface 1a and its periphery. . An annular flange portion 3c extends from the end of the protruding portion 3b toward the inside, and the flange portion 3c
Covers the peripheral edge of the end face 1d. A circular hole is formed inside the flange 3c.

The ceramic membrane filter 1 is mounted as shown in FIG. That is, the annular molded body 3 on one end side of the filter 1 is inserted into the recess 6d of the first cap 6 and fixed. A protrusion 6c is formed near the center of the main body 6a of the cap 6, and a raw water supply port 7 is provided inside the protrusion 6c. The flange 6 is provided on the periphery of the main body 6a.
b is formed, and the annular molded body 3 is held inside the flange 6b. The first seal member 4A is fixed in the gap between the flange 6b and the annular molded body 3.

The annular molded body 3 on the other end side of the ceramic membrane filter 1 is inserted into the recess 5c of the second cap 5 and fixed. A flange 5b is formed on the periphery of the disk-shaped main body 5a, and the annular molded body 3 is formed inside the flange 5b.
Has been held. The second seal member 4B is fixed in the gap between the flange 5b and the annular molded body 3. The raw water that has flowed in from the raw water supply port 7 as shown by the arrow A enters the water passage holes of the ceramic membrane filter 1 and sequentially passes through the ceramic fine pore membrane and the ceramic intermediate membrane, and from the filter side peripheral surface 1b to the arrow B. Is discharged as purified water.

According to the seal structure of this embodiment, the annular molded bodies 3 at the respective end portions of the ceramic membrane filter 1 are fitted into the first cap 6 and the second cap 5 to facilitate the operation. The filter 1 can be attached to a filtration device. Further, similarly, the filter 1 can be easily removed from the filtering device. In addition, the annular molded body 3
However, since the edge 1c at the end of the filter 1 is covered and protected, damage or chipping of this edge portion can be prevented.

The raw materials constituting the ceramic membrane filter 1 are alumina, silica, silica-alumina, mullite,
A ceramic raw material powder such as cordierite or zirconia is used. Using these raw material powders, known molding and sintering techniques are applied to obtain a porous ceramic substrate. The average pore diameter of the ceramic intermediate membrane is smaller than that of the base body, and the average pore diameter of the ceramic fine pore membrane is smaller than that of the ceramic intermediate membrane. In order to form such a filtration membrane, there are methods such as application of slurry containing ceramic particles, adhesion of a gel membrane containing ceramic particles by a sol-gel method, and high pressure compression bonding of fine powder. Further, such a filtration membrane can be formed on the side of the side surface 1b of the ceramic membrane filter 1.

The seal structure shown in FIG. 2 can also be used as a main filter medium of a water purifier of undersink type or the like. Unlike the hollow fiber membrane filter, the ceramic membrane filter 1 can be regenerated by washing with an alkaline solution and washing with an acid. Such a regeneration treatment is not possible with a hollow fiber membrane filter that is an organic substance. Since the ceramic membrane filter 1, which is a high-cost main filter medium, can be regenerated and reused as described above, the maintenance cost of the water purifier is much smaller than that of the hollow fiber membrane filter. In this respect, it is far superior to conventional home water purifiers, which have a particularly high maintenance cost.

Further, by adjusting the pore diameter of the ceramic micropore membrane of the ceramic membrane filter 1, minute organic substances such as bacteria and rust can be completely captured. For this reason, the pore size of the ceramic microporous membrane is preferably about 0.5 μm or less.
Moreover, in the case of hollow fiber membranes, the manufacturing method inevitably causes considerable variations in the pore diameter. This inevitably results from the process of stretching the organic polymer. On the other hand, the pore diameter of the ceramic microporous membrane is almost constant if the size of the raw material particles used during membrane formation is uniform, and is larger than the desired value as in the case of the hollow fiber membrane filter. No porosity occurs. As described above, in the case where the ceramic membrane filter 1 is to be regenerated, it is preferable that the constituent material thereof be alumina ceramics having an Al ₂ O ₃ component of 95% by weight or more. Such alumina ceramics are preferable because they are particularly excellent in heat resistance and resistance to acidic cleaning solutions and alkaline cleaning solutions.

As the material of the annular molded body 3, a material that is in close contact with ceramics is preferable, and a material having a small thermal expansion and thermal contraction is preferable. An engineering plastic having rubber elasticity, that is, an engineering elastomer is particularly preferable as a material satisfying both of these.

In order to regenerate the ceramic membrane filter 1 with a chemical solution, the annular molded body 3 must have durability against the chemical solution. Engineering elastomers are also preferable as such resins,
Particularly, a thermoplastic polyester elastomer having the following hard segment and soft segment is preferable.

[Chemical 1]

[Chemical 2] Such thermoplastic polyester elastomers were commercially available under the trade name "Hytrel".

As the seal members 4A and 4B, so-called O-rings and C-rings made of rubber are preferable. The seal member may be provided at two or more locations on one end. The shapes of the caps 5 and 6 can be variously changed.

[0023]

As described above, according to the present invention, by inserting the annular molded body at each end of the ceramic membrane filter into the first cap and the second cap,
The ceramic membrane filter can be easily attached to the filtration device. Also, similarly, the ceramic membrane filter can be easily removed from the filtration device. Further, since the edge of the end portion of the ceramic membrane filter is covered with the annular molded body, it is possible to prevent the edge portion from being damaged or chipped.

[Brief description of drawings]

FIG. 1A is a partial cross-sectional view showing a filter according to an embodiment of the present invention, and FIG. 1B is an enlarged view of a main part of FIG.

FIG. 2 is a partial cross-sectional view showing a state where the filter of FIG. 1 is fitted to the first cap 6 and the second cap 5.

FIG. 3 is a cross-sectional view schematically showing a seal structure by a so-called pressure bonding method.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Ceramic membrane filter 1a End surface 1c Edge of end surface 2 Coating film 3 Annular molded body 4A First sealing member 4B Second sealing member 5 Second cap 6 First cap 7 Raw water supply port

Claims (2)

[Claims] 1. A ceramic membrane filter having a columnar outer contour, a coating film for plugging both lengthwise end faces of the ceramic membrane filter, and the ceramic membrane so as to cover at least the edge of the end face. A filter comprising: an annular molded body made of a thermoplastic resin, which is fixed to both ends of the filter. 2. A ceramic membrane filter having a columnar outer contour, a coating film for plugging both lengthwise end faces of the ceramic membrane filter, and the ceramic membrane so as to cover at least the edge of the end face. An annular molded body made of a thermoplastic resin fixed to both ends of the filter, and a raw water supply port fitted and fixed to the annular molded body on one end side of the ceramic membrane filter. A first cap, a first sealing member fixed in a gap between the first cap and the annular molded body, and a ring-shaped molded body on the other end side of the ceramic membrane filter. A sealing structure for a ceramic membrane filter, comprising: a second cap fixed and fixed; and a second sealing member fixed in a gap between the second cap and the annular molded body. .