JP3217831B2 - Water purifier - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a water purifier.

[0002]

2. Description of the Related Art In recent years, it has been strongly pointed out that tap water has become bad. The causes include chlorine, rust, odor, bacteria, and the like. Furthermore, recently, it has been pointed out that trihalomethane, which is a carcinogen, exists in tap water. Under these circumstances, household water purifiers that remove harmful substances for 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 completely removed by activated carbon by the microfiltration action of the hollow fiber membrane. One example is disclosed in JP-A-2-198684.

[0003]

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 periodically remove the clogging in order to maintain the filter function. In order to remove the clogging, it is conceivable to carry out a chemical cleaning or to remove the organic matter causing the clogging by incineration. However, since the hollow fiber membrane is an organic membrane made of plastic and has poor chemical resistance and heat resistance, such a method cannot be adopted at all.

[0004] Therefore, it is conceivable to pass the washing water, but in this case, a pressure higher than that during the filtration is applied. When such a high pressure is applied to the hollow fiber membrane which is an organic membrane, pores of the membrane are widened, resulting in impairing the filter function. This point is the same even when a method of washing by applying a reverse pressure to the filter is adopted.

After all, although a hollow fiber membrane filter has a high purification function, it cannot be reused when clogging occurs and must be discarded, and the maintenance cost of the water purifier is high. In particular, considering the use in ordinary households, hollow fiber membrane filters are not suitable because of high maintenance costs.

SUMMARY OF THE INVENTION An object of the present invention is to filter general bacteria, rust, etc., to reuse the filter portion repeatedly, and to make the lump of water molecules smaller and more uniform. It is to provide a water purifier.

[0007]

According to the present invention, there is provided a ceramic membrane having at least a filter layer containing activated carbon, an aluminum plate and a large number of water holes inside an outer case having a raw water inlet and a purified water outlet. The filter is fixed, a ceramic intermediate membrane having a smaller pore diameter than the ceramic carrier, and a ceramic pore membrane having a smaller pore diameter are provided on the surface of the ceramic membrane filter on the water-permeation hole side of the ceramic carrier. The present invention relates to a water purifier configured to transmit through a filtration layer and the ceramic membrane filter, and configured to ionize water between the filtration layer and the aluminum plate.

"Filtration layer containing at least activated carbon"
Includes a filtration layer made of activated carbon only, and also a filtration layer made of a mixture of activated carbon and a mineral-eluting substance. As the mineral eluting substance, coral sand is preferable. Further, in the water purifier of the present invention, in addition to the filtration layer, aluminum plate, ceramic membrane filter, other substances,
For example, a filtration layer made of coral sand or zeolite can be provided.

[0009]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiments embodying the present invention will be described below in detail with reference to the drawings. FIG. 3 is a perspective view showing an example of an attached state of the water purifier 1A of the present embodiment. In this installation example, the kitchen of a small house such as a general home is targeted. The water purifier 1A (or 1B described later) is attached to the lower side of the kitchen sink S. Stopcock M and water purifier 1A
The raw water inlet of (1B) is connected by a hose 28A, and the purified water outlet of the water purifier 1A (1B) and the purified water faucet W are connected by a hose 28B.

FIG. 1 is a longitudinal sectional view of a water purifier 1A according to this embodiment, and FIG. 2 is a partially cutaway perspective view of the water purifier 1A. The outer case of the water purifier 1A is formed by fitting a substantially cylindrical main body 2 without a bottom and a bottom cover 3 to each other. A raw water inlet 2a is provided on the periphery of the upper end surface of the main body 2, and a purified water outlet 2b is provided near the center. Substantially annular holding plate 2c
Extends downward from the upper end wall surface of the main body 2.
A male screw 2 d is formed on the outer periphery of the lower part of the main body 2. The bottom cover 3 has a cylindrical shape with an open upper end, and has a female screw 3a formed on an inner peripheral surface thereof. The inner peripheral surface of the bottom cover 3 and the lower peripheral surface of the main body 2 can be fitted to each other.
The outer case is formed by screwing d and the female screw 3a.

A hollow inner case 5 having a substantially cylindrical shape as a whole is fixed inside the outer case. The outer peripheral edge of the upper end of the inner case 5 is fitted into the inner peripheral surface of the holding plate 2c. A circular lid 5e is formed at the upper end of the inner case 5, and an annular protrusion 5d is formed downward on the lower wall surface of the lid 5e. A cover 5e is provided at a position outside the projection 5d.
A predetermined number of through holes 5c are formed along the peripheral edge of. A substantially annular support plate 5b extending horizontally protrudes from a lower inner peripheral surface of the inner case 5, and several substantially rectangular legs 5a are formed below the support plate 5b. .
Each leg 5a is supported by the wall surface of the bottom cover 3, and each leg 5a
a contacts the positioning small protrusion 3b. Support plate 5
Above b, a small protrusion 5f is formed.

The outer case and the inner case 5 are arranged substantially concentrically, and a cylindrical gap 30 is formed between the inner peripheral surface of the main body 2 and the outer peripheral surface of the inner case 5. Gap 30
Is connected to the raw water inlet 2a. A filtration membrane 4A made of zeolite is provided in the gap 30, a filtration membrane 8 made of activated carbon is provided below the filtration membrane 4A, and a filtration membrane 9 made of coral sand is provided below the filtration membrane 8. ing. Each of the filtration membranes 4A, 8, and 9 has a cylindrical shape and is in contact with each other.

An annular aluminum plate 6A is installed on the bottom surface of the bottom cover 3, and an outer peripheral edge of the aluminum plate 6A is
The inner peripheral edge of the aluminum plate 6A is in contact with the leg 5a.
Abut. Between the filtration membrane 9 and the aluminum plate 6A,
There are some gaps. O-ring 7 between body 2 and bottom lid 3
Seal with A.

A substantially cylindrical ceramic membrane filter 10 is fixed inside the inner case 5. The lower end surface of the ceramic membrane filter 10 is placed on the inner end of the support plate 5b, and the outer periphery of the lower end of the filter 10 abuts on the small projection 5f and is positioned. The outer periphery of the upper end of the ceramic membrane filter 10 has a protrusion 5d.
And is positioned. In this example, a flat packing 18 is used to seal between the upper end surface of the filter 10 and the lid 5e.
This part may be sealed with an O-ring. The ceramic membrane filter 10 is installed substantially concentrically with the inner case 5, and a substantially cylindrical gap is formed between the filter 10 and the inner case 5. This gap communicates with the through hole 5c. O-ring 7C between the holding plate 2c and the inner case 5
The space between the ceramic membrane filter 10 and the support plate 5b is sealed by an O-ring 7B.

A number of water holes 19 are provided inside the ceramic membrane filter 10, and each water hole 19 extends in the longitudinal direction of the filter 10 and opens at both end surfaces in the longitudinal direction of the filter 10. I have. A glass seal is applied to both end surfaces so that raw water can enter only into the water passage hole 19. The whole of the ceramic membrane filter 10 is made of a ceramic carrier having relatively large particles. On the peripheral wall of the water passage hole 19, a ceramic intermediate membrane having a smaller pore diameter and a ceramic porous membrane having a smaller pore diameter are provided. At this time, a ceramic intermediate film is provided between the ceramic microporous membrane and the ceramic carrier so that the ceramic microporous membrane surrounds and exposes the water holes 19.

Next, the flow of water will be described. First, raw water flows into the gap 30 as shown by the arrow A from the raw water inlet 2a. This raw water flows as shown by arrow B, and the filtration layer 4A,
8 and 9 are sequentially transmitted, pass between the legs 5 a as shown by the arrow C, and enter the water passage hole 19 as shown by the arrow D. Then, it passes through the ceramic porous membrane, the ceramic intermediate membrane, and the ceramic carrier, and leaks from the outer peripheral surface of the ceramic membrane filter 10 as shown by an arrow E. The purified water thus purified rises between the outer peripheral surface of the ceramic membrane filter 10 and the inner wall surface of the inner case 5a, passes through the through hole 5c as shown by the arrow F, and
Collected in. Finally, the purified water passes through the purified water outlet 2b as shown by the arrow G and is sent to the purified water faucet. Operate the air release knob 20 as necessary.

In the water purifier of this embodiment, the ceramic membrane filter 10 is used as a filter material. Unlike a hollow fiber membrane filter, such a filter 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. Prior to this cleaning treatment, the ceramic membrane filter 10 can be heated at a temperature in the range of, for example, 300 ° C. to 1200 ° C. for a certain period of time to decompose organic substances in advance. Since the ceramic membrane filter 10, which is a high-cost main filter medium, can be regenerated and reused, the maintenance cost of the water purifier 1A is extremely small as compared with the hollow fiber membrane filter. In this regard, it is particularly superior to conventional home water purifiers, which are particularly expensive to maintain.

Further, by adjusting the pore size of the ceramic porous membrane of the ceramic membrane filter 10, minute organic substances such as bacteria and rust can be completely captured. For this reason, it is preferable that the pore diameter is about 0.5 μm or less. In addition, in the case of the hollow fiber membrane, a considerable variation in the pore diameter is inevitably caused by the manufacturing method. This inevitably arises from the process of stretching organic polymers. On the other hand, the pore size of the ceramic porous membrane is almost constant if the size of the raw material particles used in forming the membrane is made uniform, and is larger than a desired value as in the case of the hollow fiber membrane filter. No pores are formed.

As a constituent material of the ceramic membrane filter, alumina ceramics or the like is preferable. The use of alumina ceramics having an Al ₂ O ₃ component of 95% by weight or more is particularly excellent in heat resistance at 1200 ° C. or less and resistance to an acidic cleaning solution or an alkaline cleaning solution, which is preferable.

Further, the ceramic membrane filter of the present embodiment
In 10, an asymmetric structure is adopted in which an intermediate layer and a pore layer are provided on the surface of the ceramic carrier having a relatively large pore diameter on the side of the water passage holes 19. With such an asymmetric membrane structure, it is possible to reduce the pressure loss as compared with the single-layer structure, and to capture the filtration particles on the surface of the fine-grain layer, so that the backwash regenerating property is good. It has become something.

In the water purifier of this embodiment, first, heavy metal ions such as heavy water, copper, cadmium, and hexavalent chromium, and unnecessary minerals can be removed by the filtration membrane 4A made of zeolite. Next, in the filtration layer 8 made of activated carbon, chlorine and trihalomethane are removed, and minerals are eluted from the coral sand.

Further, since water flows between the filtration layer 8 made of activated carbon and the aluminum plate 6A, a voltaic cell is formed, and a voltage of about 1 volt is generated. This ionizes the water molecules and reduces the size of the water molecules,
And it is made uniform and easily absorbed by the body. Moreover, minerals eluted from the coral sand are also ionized, so that they are very easily absorbed into the body. The microscopic bacteria and rust that have passed through each of the filtration membranes are also completely removed by the ceramic membrane filter 10 as described above.

1 and 2, a molecular sieve other than zeolite may be used as a material of the filtration layer 4A, or another functional material may be used. In addition, a mixture of activated carbon and coral sand can be used as a material for the filtration layer 8, and in this case, the filtration layer 9 is not necessary.

FIG. 4 is a partially cutaway perspective view showing the water purifier 1B. The same members as those in the water purifier 1A are denoted by the same reference numerals, and description thereof will be omitted. An aluminum plate 6B is fixed in a belt shape on the inner peripheral surface of the main body 2 of the outer case. A filtration layer 4B made of zeolite is provided on the upper side of the aluminum plate 6B. The inner case 15 has a substantially cylindrical shape, and the lower end of the inner case 15 contacts the bottom cover 3.
A circular lid 15b is provided at the upper end of the inner case 15, and a large number of through holes 15c are formed in the lid 15b. At the lower end of the outer peripheral surface of the inner case 15, a flange 29A having an L-shaped cross section and a flat ring shape is protruded. Immediately below the filter layer 4B on the outer peripheral surface of the inner case 15, a flange 29B having an L-shaped cross section and a flat ring shape is projected.

At the lower end of the inner case 15, there is no passage of raw water. Instead, a number of water inlets 15a are provided on the side peripheral surface of the inner case 15. In the present embodiment, each water passage 15a has an elongated and substantially rectangular shape, and both ends thereof are arc-shaped. In addition, the water inlet 15a extends in the vertical direction of the inner case 15.
Are arranged in a line, and the water passage openings 15a are regularly arranged at regular intervals in the circumferential direction of the inner case 15. In FIG. 4, a part of the wall surface of the inner case 15 is cut away, including the water inlet 15a.

A substantially cylindrical filter layer 40 is provided between the flanges 29A and 29B. This filtration layer 40 is made of a mixture of activated carbon and coral sand. All the water inlets 15a are covered by the filter layer 40.

The raw water flows into the raw water inlet 2a as shown by the arrow A, passes through the filtration layer 4B, and flows into the gap 30. Since the aluminum plate 6B and the filtration layer 40 containing activated carbon face each other with the gap 30 interposed therebetween, a voltaic cell is formed between them, and water is ionized. Next, the ionized water permeates the filtration layer 40, and the arrow H is inserted in the water passage 15a.
And reaches the outer peripheral surface of the ceramic membrane filter 10. Then, as shown by arrow I, water permeates through the ceramic membrane filter, enters water passage hole 19, and rises due to the water pressure. The filtered purified water flows out of the upper end opening of the water passage hole 19, further flows out of the through hole 15c, and finally the purified water outlet 2b
Flows out as shown by arrow G.

In the water purifier 1B shown in FIG.
Can be separated into a filtration layer made of activated carbon and a filtration layer made of coral sand. Water purifier 1A,
In 1B, another filtering member or a filtering layer can be further provided. Further, the external shape of the ceramic membrane filter may be changed, for example, to have a square pillar shape or a hexagonal pillar shape.

[0029]

In the water purifier of the present invention, a ceramic membrane filter is used as a main filter medium for removing microscopic bacteria and rust, etc.
It can be regenerated and reused by washing with an acid, heat treatment or the like. As described above, since a high-cost filter medium having a high filtering ability can be reused, the maintenance cost of the water purifier is extremely reduced, and it is particularly excellent for household use.

Furthermore, since a filtration layer containing at least activated carbon and an aluminum plate are provided, when water as an electrolyte flows between them, a voltaic cell is formed and water molecules are ionized. As a result, the size of the lump of water molecules is reduced and uniformized, and the water molecules are easily absorbed by the body. In addition, the water molecules undergo microfiltration again when passing through the ceramic membrane filter, so that the mass of water molecules is made more uniform.

[Brief description of the drawings]

FIG. 1 is a longitudinal sectional view of a water purifier 1.

FIG. 2 is a partially broken perspective view of a water purifier 1A.

FIG. 3 is a perspective view showing an example of an attached state of a water purifier.

FIG. 4 is a partially broken perspective view of a water purifier 1B.

[Explanation of symbols]

 1A, 1B Water purifier 2 Body of outer case 2a Raw water inlet 2b Purified water outlet 3 Bottom lid of outer case 4A, 4B Filtration layer made of zeolite 5, 15 Inner case 6A, 6B Aluminum plate 8 Filtration layer made of activated carbon 9 Coral Filtration layer made of sand 10 Ceramic membrane filter 19 Water vent 40 Filtration layer made of a mixture of activated carbon and coral sand

Claims (1)

(57) [Claims] Inside of claim 1 outer case having a raw water inlet and clean water outlet, and the ceramic membrane filter is fixed with a filtering layer and the aluminum plate and the plurality of water passing holes containing at least activated carbon, ceramic membranes In the filter
A ceramic carrier is placed on the surface on the water hole side of the ceramic carrier.
Ceramic interlayer with small pore size
Ceramic pore membrane is provided, raw water is configured to pass through at least the filtration layer and the ceramic membrane filter, and is configured to be able to ionize water between the filtration layer and the aluminum plate. There is a water purifier.