JPH0889944A - Water purifier - Google Patents

Abstract

PURPOSE: To remove lead, chlorine odor, mold odor, etc., and to obtain a water purifier from which a large amt. of the adsorbed lead is never discharged into city water by providing the purifier with a section packed with activated carbon and a calcium phosphate ceramic. CONSTITUTION: A first section 1a packed with a mixture of granular and/or fibrous activated carbon, granular and/or fibrous hydroxyapatite and a calcium phosphate ceramic of bone meal, etc., and a second section 1b packed with a hollow-fiber membrane 3 are respectively formed in a case 1. The first section 1a and the second section 1b are successively arranged from the upstream side toward the downstream side with respect to the water current shown by the arrow, and a perforated partition plate 4 is set between the first section 1a and the second section 1b. Further, the downstream end of the membrane 3 is held by an end plate 5, and a perforated partition plate 6 is furnished on the upstream side of the mixture 2 to remove the coarse iron rust, etc., in the water current.

Description

Detailed Description of the Invention

[0001]

TECHNICAL FIELD The present invention relates to a water purifier including a water purifier for drinking water.

[0002]

2. Description of the Related Art In the water purifiers for drinking water which have hitherto been provided on the market, harmful heavy metals such as lead dissolved in drinking water, chlorine odors and musty odors have been removed by using activated carbon.

[0003]

In the conventional water purifiers for drinking water, the lead adsorption performance of activated carbon sharply deteriorates with time, or a large amount of lead adsorbed on activated carbon is contained in tap water (especially in high temperature tap water). There was a problem such as being released (in water). The present invention has been made in view of the above problems, removes lead, chlorine odor, musty odor, etc., and there is no possibility that lead adsorption performance will sharply decrease over time, and a large amount of adsorbed lead in tap water. The purpose is to provide a water purifier that does not release.

[0004]

In order to solve the above problems, the present invention provides a water purifier characterized by comprising a compartment filled with activated carbon and calcium phosphate ceramics. In the present invention, activated carbon removes mainly chlorine odor, musty odor, etc. in water, and calcium phosphate-based ceramics remove lead in water. There is no possibility that the lead adsorption performance of the calcium phosphate-based ceramics will deteriorate sharply with time. There is no possibility that a large amount of lead adsorbed on the calcium phosphate ceramics will be released into water. Even if the lead adsorbed on the activated carbon is released into water, the lead is adsorbed on the calcium phosphate ceramics filled in the same compartment as the activated carbon,
There is no possibility that a large amount of lead will be released into the permeated water discharged from the water purifier. In a preferred embodiment of the present invention, the calcium phosphate ceramics is bone charcoal. By using bone charcoal as the calcium phosphate ceramics, a water purifier having particularly excellent lead removal performance can be obtained.
In a preferred embodiment of the present invention, the volume% of the calcium phosphate ceramics with respect to the sum of the activated carbon and the calcium phosphate ceramics is 1% or more and less than 25%.
By setting the volume% of calcium phosphate ceramics to the sum of activated carbon and calcium phosphate ceramics to be 1% or more, the lead adsorbed on the activated carbon at the start of water passage is eluted into the permeate and the lead concentration in the permeate is There is no risk of becoming higher than the lead concentration in the raw water before passing through the water purifier. In a preferred aspect of the present invention, the volume percentage of the calcium phosphate ceramics with respect to the sum of the activated carbon and the calcium phosphate ceramics is 25% or more. By setting the volume% of calcium phosphate-based ceramics to the sum of activated carbon and calcium phosphate-based ceramics to 25% or more, it is possible to prevent the situation where the lead removal performance of the water purifier sharply deteriorates and to improve the lead removal performance of the water purifier. It can be maintained for a long time. In a preferred embodiment of the present invention,
Granular and / or fibrous activated carbon and granular and / or fibrous calcium phosphate ceramics are filled in the compartment. In a preferred embodiment of the present invention, granular and / or fibrous activated carbon and granular and / or fibrous calcium phosphate ceramics are mixed and filled in the compartment. In a preferred embodiment of the present invention, the compartment is filled with granular and / or fibrous activated carbon carrying calcium phosphate ceramic particles. In a preferred aspect of the present invention, the compartment is filled with granular and / or fibrous calcium phosphate-based ceramics carrying activated carbon particles. In a preferred embodiment of the present invention, a granular and / or fibrous base material carrying calcium phosphate-based ceramic particles and a granular and / or
Alternatively, it is mixed with fibrous activated carbon and filled in the compartment. In a preferred embodiment of the present invention, a granular and / or fibrous base material carrying activated carbon particles and a granular and / or
Alternatively, fibrous calcium phosphate-based ceramics are mixed and filled in the compartment. In a preferred embodiment of the present invention, the compartment is filled with a laminate having a layer of granular and / or fibrous activated carbon and a layer of granular and / or fibrous calcium phosphate ceramics.
In a preferred embodiment of the present invention, the laminate is formed by winding a non-woven fabric of activated carbon fibers on the surface of which granular and / or fibrous calcium phosphate ceramics are dispersed. In a preferred embodiment of the present invention,
The laminated body is formed by integrally winding a sheet-like porous base material carrying calcium phosphate-based ceramic particles together with a non-woven fabric of activated carbon fibers. In a preferred embodiment of the present invention, the compartment is filled with a granular and / or fibrous base material carrying activated carbon particles and calcium phosphate-based ceramic particles. In a preferred aspect of the present invention, the compartment is filled with a laminate formed by laminating layers containing granular and / or fibrous activated carbon and granular and / or fibrous calcium phosphate ceramics. In a preferred embodiment of the present invention, the laminate is formed by winding a non-woven fabric-like base material on the surface of which granular and / or fibrous activated carbon and granular and / or fibrous calcium phosphate ceramics are sprinkled. . In a preferred embodiment of the present invention, the laminate is formed by integrally winding a sheet-like porous base material carrying activated carbon particles and calcium phosphate-based ceramic particles together with a non-woven material. By packing the activated carbon and the calcium phosphate-based ceramics in the same compartment, the size of the water purifier can be made smaller than in the case where both are packed in different compartments. Activated carbon and calcium phosphate-based ceramics need to be filled in the compartment in a manner that allows water to permeate. When the granular and / or fibrous activated carbon and the granular and / or fibrous calcium phosphate ceramics are filled in the compartment, water can pass through the activated carbon and the calcium phosphate ceramics. Any mode may be used for filling the compartments with granular and / or fibrous activated carbon and granular and / or fibrous calcium phosphate ceramics. Granular and / or fibrous activated carbon and granular and / or fibrous calcium phosphate-based ceramics may be mixed and filled in the compartment, and the granular and / or fibrous activated carbon carrying calcium phosphate-based ceramic particles Granules and / or fibrous calcium phosphate-based ceramics that carry activated carbon particles may be filled in the compartments, and the compartments may be filled with granular and / or fibrous base materials that carry calcium phosphate-based ceramic particles. May be mixed with granular and / or fibrous activated carbon to fill the compartment, and a granular and / or fibrous base material carrying activated carbon particles and a granular and / or fibrous calcium phosphate ceramics The mixture may be mixed and filled in the compartment, and a granular and / or fibrous layer of activated carbon and a granular and / or fibrous calcium phosphate A laminate having a layer of the system ceramics may be filled in the compartment. The laminated body may be formed by winding a nonwoven fabric of activated carbon fibers in which granular and / or fibrous calcium phosphate-based ceramics are scattered on the surface, and a sheet-like porous base material carrying calcium phosphate-based ceramic particles is formed. It may be formed by being integrally wound with a non-woven fabric of activated carbon fiber. In addition, a granular and / or fibrous base material carrying activated carbon particles and calcium phosphate-based ceramic particles may be filled in the compartment, and granular and / or fibrous activated carbon and granular and / or fibrous calcium phosphate-based materials may be filled. You may fill the said compartment with the laminated body formed by laminating | stacking the layer containing ceramics. The laminate may be formed by winding a non-woven fabric-like substrate on the surface of which granular and / or fibrous activated carbon and granular and / or fibrous calcium phosphate-based ceramics are sprinkled, and the activated carbon particles and calcium phosphate-based It may be formed by integrally winding a sheet-like porous base material carrying ceramic particles with a non-woven fabric-like base material. In any of the above cases, the size of the water purifier can be reduced as compared with the case where activated carbon and calcium phosphate-based ceramics are filled in separate compartments. In a preferred embodiment of the present invention,
The water purifier is a water purifier for drinking water. When the water purifier is a water purifier for drinking water, the compact water purifier for drinking water removes chlorine odor, musty odor, and the like from tap water that is drinking water, and also removes lead. There is no possibility that the lead adsorption performance of the drinking water purifier will suddenly decrease with time, and that a large amount of lead will not be released into the permeated water discharged from the drinking water purifier.

[0005]

BEST MODE FOR CARRYING OUT THE INVENTION

(1) Example A drinking water purifier according to a first example of the present invention will be described with reference to FIG. As shown in FIG. 1 (a), in a case 1, granular and / or fibrous activated carbon and granular and / or fibrous hydroxyapatite, tricalcium phosphate, monocalcium phosphate, dicalcium phosphate, calcium pyrophosphate, phosphorus Formed are a first section 1a filled with a mixture 2 of calcium phosphate-based ceramics such as tetracalcium acid, 8-calcium phosphate, bone charcoal and bone powder, and a second section 1b filled with a hollow fiber filtration membrane 3. . The compartments are arranged in the order of a first compartment 1a and a second compartment 1b from upstream to downstream with respect to the water flow indicated by the arrow in FIG. A porous partition plate 4 is arranged between the first section 1a and the second section 1b. Second section 1b
The downstream end of the hollow fiber filtration membrane 3 is held by an end plate 5 as shown in FIG. First section 1a
A porous partition plate 6 for removing coarse iron rust and the like in the water stream is disposed upstream of the mixture 2 of activated carbon and calcium phosphate ceramics therein.

In this water purifier, when the drinking water passes through the filter layer of the mixture 2 of activated carbon and calcium phosphate ceramics and the filter layer of the hollow fiber filtration membrane 3, the mixture 2
The activated carbon contained therein mainly removes chlorine odor, musty odor, etc. in the drinking water, the calcium phosphate ceramics remove lead in the drinking water, and the hollow fiber filtration membrane 3 removes other pollutants, microorganisms and the like in the drinking water. Since the activated carbon and the calcium phosphate-based ceramics filled in the compartment 1a are granular and / or fibrous, they do not hinder the permeation of drinking water. The lead adsorption performance of the calcium phosphate ceramics is maintained for a long time. There is no possibility that a large amount of lead adsorbed on the calcium phosphate ceramics will be released into drinking water. Even if the lead adsorbed on the activated carbon is released into the drinking water, the lead is adsorbed on the calcium phosphate-based ceramics filled in the compartment 1a together with the activated carbon, so that a large amount of lead is introduced into the permeated water discharged from the water purifier. Is not likely to be released. Since the activated carbon and the calcium phosphate ceramics are filled in the same compartment 1a, the size of the water purifier is smaller than that in the case where both are filled in different compartments.

A drinking water purifier according to a second embodiment of the present invention will be described with reference to FIG. In this embodiment, the first compartment 1a is filled with granular activated carbon 22c and / or fibrous activated carbon 22d carrying calcium phosphate ceramics particles 22a as shown in FIGS. 2 (a) and 2 (b). There is. Granular activated carbon 22c and / or fibrous activated carbon 22d, and calcium phosphate ceramic particles 22
As a method of supporting a, for example, the method proposed by the inventor of the present invention in Japanese Patent Application No. 6-70189 may be adopted. According to the above method, the glass containing CaO and SiO ₂ as the main components and the granular activated carbon 22c and / or the fibrous activated carbon 22d are opposed to each other with a space therebetween, and hydroxyapatite having a substantially saturated or supersaturated concentration is formed. Activated carbon 2 by flowing the component aqueous solution from the glass side toward activated carbon 22c and / or 22d.
2c and / or 22d are permeated and activated carbon 22c and / or
Alternatively, the hydroxyapatite particles are carried on the activated carbons 22c and / or 22d by stopping the permeation of the aqueous solution after growing the hydroxyapatite particles to such an extent that the pores of 22d are not blocked. Except for the above, the structure of the drinking water purifier according to the present embodiment is the same as the structure of the drinking water purifier according to the first embodiment.

Also in this drinking water purifier, as in the drinking water purifier according to the first embodiment, the drinking water is granular activated carbon 2 carrying calcium phosphate ceramics 22a.
2c and / or fibrous activated carbon 22d and the hollow fiber filtration membrane 3 pass through the filtration layer, the activated carbon 22c and / or 22d removes chlorine odor, mold odor, etc. Are removed, and other pollutants, microorganisms, etc. are removed by the hollow fiber filtration membrane 3. The lead adsorption performance of the calcium phosphate ceramics 22a is maintained for a long time, and there is no possibility that a large amount of lead adsorbed on the calcium phosphate ceramics 22a will be released into tap water. Activated carbon 22c and /
Alternatively, since 22d and the calcium phosphate-based ceramics 22a are filled in the single compartment 1a, the size of the water purifier is reduced as compared with the case where both are filled in separate compartments.

A drinking water purifier according to a third embodiment of the present invention will be described with reference to FIG. In this embodiment, the first compartment 1a is filled with granular calcium phosphate-based ceramics 32a carrying activated carbon particles 32c and / or fibrous calcium phosphate-based ceramics 32b as shown in FIGS. 3 (a) and 3 (b). Has been done. Activated carbon particles 32
c is supported on the granular calcium phosphate ceramics 32a and / or the fibrous calcium phosphate ceramics 32b by thermal spraying. Except for the above, the structure of the drinking water purifier according to the present embodiment is the same as the structure of the drinking water purifier according to the first embodiment.

Also in the drinking water purifier of the present invention, as in the drinking water purifier according to the first embodiment, the drinking water is granular calcium phosphate-based ceramics 32a carrying activated carbon particles 32c and / or fibrous calcium phosphate. When passing through the filtration layer of the system ceramics 32b and the filtration layer of the hollow fiber filtration membrane 3, the activated carbon 32c removes chlorine odor, mold odor, etc., and the calcium phosphate ceramics 32a, 32
Lead is removed by b, and other pollutants, microorganisms, etc. are removed by the hollow fiber filtration membrane 3. The lead adsorption performance of the calcium phosphate-based ceramics 32a and 32b is maintained for a long time, and the calcium phosphate-based ceramics 32 is
There is no possibility that a large amount of lead adsorbed on a and 32b will be released into tap water. Activated carbon 32c and calcium phosphate-based ceramics 32a and / or 32b are a single section 1a
Since it is filled in the inside, the size of the water purifier is smaller than that in the case where both are filled in separate compartments.

A drinking water purifier according to a fourth embodiment of the present invention will be described with reference to FIG. In this embodiment, in the first section 1a, as shown in FIGS. 4 (a) to 4 (d), a granular base material 42e and / or a fibrous base material 42f carrying calcium phosphate ceramics particles 42a and a granular base material 42f. The activated carbon 42c and / or the fibrous activated carbon 42d are mixed with each other. The calcium phosphate-based ceramic particles 4 are formed on the granular base material 42e and / or the fibrous base material 42f.
As a method for supporting 2a, for example, the same method as in the second embodiment can be adopted. In this case, the glass containing CaO and SiO ₂ as the main components and the base material 42e and / or 42f are opposed to each other with a space therebetween, and a substantially saturated or supersaturated aqueous solution of hydroxyapatite component is applied from the glass side. Flowing toward the material 42e and / or 42f, the base material 42e and / or 42
After permeating f and growing particles of hydroxyapatite,
By stopping the permeation of the aqueous solution, the base material 42e and / or
Alternatively, particles of hydroxyapatite are carried on 42f. The materials of the granular base material 42e and the fibrous base material 42f are cellulose, polysulfone, polyamide, polyvinyl alcohol, nylon, polystyrene, polypropylene, as disclosed by the inventor of the present invention in Japanese Patent Application No. 6-70189. Any of organic polymer materials such as polycarbonate and polyethylene, ceramics, metals, etc. may be used. The base materials 42e and 42f may be porous bodies or may not be porous bodies. Except for the above, the structure of the drinking water purifier according to the present embodiment is the first
The structure is the same as that of the drinking water purifier according to the embodiment.

Also in this drinking water purifier, the drinking water purifier has a granular base material 42 carrying the calcium phosphate ceramics 42a as in the drinking water purifier according to the first embodiment.
e and / or fibrous base material 42f and granular activated carbon 42c
And / or activated carbon 42 as it passes through the filtration layer of the mixture with fibrous activated carbon 42d and the filtration layer of the hollow fiber filtration membrane 3.
Chlorine odor, musty odor, etc. are removed by c and / or 42d, lead is removed by the calcium phosphate ceramics 42a, and other pollutants, microorganisms, etc. are removed by the hollow fiber filtration membrane 3. Calcium phosphate ceramics 42
The lead adsorption performance of a is maintained for a long time, and there is no possibility that a large amount of lead adsorbed on the calcium phosphate ceramics 42a will be released into tap water. Activated carbon 42c
And / or 42d and calcium phosphate ceramics 4
Since 2a and 2a are filled in a single compartment 1a, the size of the water purifier is reduced as compared with the case where both are filled in separate compartments.

A drinking water purifier according to a fifth embodiment of the present invention will be described with reference to FIG. In the present embodiment, as shown in FIGS. 5A to 5D, the granular base material 52e and / or the fibrous base material 52f carrying the activated carbon particles 52c and the granular calcium phosphate are provided in the first section 1a. A mixture with the ceramics 52a and / or fibrous calcium phosphate ceramics 52b is filled. The activated carbon particles 52c are carried on the granular base material 52e and / or the fibrous base material 52f by thermal spraying. As the material of the granular base material 52e and the fibrous base material 52f, cellulose, polysulfone, polyamide, polyvinyl alcohol, nylon,
Organic polymer materials such as polystyrene, polypropylene, polycarbonate and polyethylene can be used. Base material 52
e and 52f may be porous bodies or may not be porous bodies. Except for the above, the structure of the drinking water purifier according to the present embodiment is the same as the structure of the drinking water purifier according to the first embodiment.

Also in the present water purifier for drinking water, similar to the water purifier for drinking water according to the first embodiment, the drinking water is a granular base material 52e carrying activated carbon particles 52c and / or a fibrous base material. 52f and granular calcium phosphate ceramics 5
When passing through the filtration layer of the mixture of 2a and / or fibrous calcium phosphate-based ceramics 52b and the filtration layer of the hollow fiber filtration membrane 3, activated carbon 52c removes chlorine odor, musty odor, etc., and calcium phosphate-based ceramics 52
Lead is removed by a and 52b, and other pollutants, microorganisms, etc. are removed by the hollow fiber filtration membrane 3. The lead adsorption performance of the calcium phosphate-based ceramics 52a and 52b is maintained for a long time, and there is no possibility that a large amount of lead adsorbed on the calcium phosphate-based ceramics 52a and 52b will be released into tap water. Since the activated carbon 52c and the calcium phosphate ceramics 52a and / or 52b are filled in the single compartment 1a, the size of the water purifier is smaller than that in the case where both are filled in separate compartments.

A drinking water purifier according to a sixth embodiment of the present invention will be described with reference to FIG. In this embodiment, in the first section 1a, as shown in FIG. 6 (a), granular and / or fibrous calcium phosphate-based ceramics 6 is formed on the surface.
A laminate 62 having a layer of granular and / or fibrous calcium phosphate ceramics 62a and a layer of non-woven fabric 62c made of activated carbon fibers, which is formed by winding a non-woven fabric 62c made of activated carbon fibers sprinkled with 2a, is filled. Alternatively, as shown in FIG. 6 (b), a calcium phosphate-based ceramic particles 62a 'formed by integrally winding a sheet-like porous base material 62e carrying calcium phosphate-based ceramic particles 62a' with a nonwoven fabric 62c 'made of activated carbon fiber. Non-woven fabric consisting of a layer of carbon and activated carbon fiber 62
A stack 62 'having layers c'is filled in the first compartment 1a. The sheet-like porous base material 62e may be any sheet-like and porous material, such as a stainless steel mesh, a glass fiber sheet, a non-woven fabric, and a plastic mesh. The method of supporting the calcium phosphate-based ceramic particles 62a 'on the sheet-shaped porous base material 62e is as follows.
This is similar to the fourth embodiment. Except for the above, the structure of the drinking water purifier according to the present embodiment is the same as the structure of the drinking water purifier according to the first embodiment.

Also in the drinking water purifier, drinking water is granular and / or similar to the drinking water purifier according to the first embodiment.
Alternatively, when passing through the filtration layer of the laminated body 62 having the layer of fibrous calcium phosphate-based ceramics 62a and the layer of the nonwoven fabric 62c made of activated carbon fiber and the filtration layer of the hollow fiber filtration membrane 3, or the calcium phosphate-based ceramics particles. When passing through the filtration layer of the laminate 62 'having the layer of 62a' and the layer of the nonwoven fabric 62c 'of the activated carbon fiber and the filtration layer of the hollow fiber filtration membrane 3, the nonwoven fabric 62 of the activated carbon fiber.
Chlorine odor, musty odor, etc. are removed by c and 62c ', and granular and / or fibrous calcium phosphate-based ceramics 6
Lead is removed by 2a and calcium phosphate-based ceramic particles 62a ', and other pollutants, microorganisms, etc. are removed by the hollow fiber filtration membrane 3. The lead adsorption performance of the calcium phosphate ceramics 62a and 62a 'is maintained for a long time, and the calcium phosphate ceramics 62
There is no possibility that a large amount of lead adsorbed on a and 62a 'will be released into tap water. Nonwoven fabric 62c made of activated carbon fiber,
62c 'and calcium phosphate ceramics 62a, 6
Since 2a 'and 1a are filled in a single compartment 1a, the size of the water purifier is smaller than that in the case where both are filled in separate compartments.

A drinking water purifier according to a seventh embodiment of the present invention will be described with reference to FIG. In this embodiment, as shown in FIGS. 7A and 7B, the granular base material 72e and / or the fibrous base material 72f supporting the calcium phosphate-based ceramic particles 72a and the activated carbon particles 72c are in the first section. 1a is filled. The method of supporting the calcium phosphate-based ceramic particles 72a on the granular base material 72e and / or the fibrous base material 72f is the same as in the fourth embodiment. The activated carbon particles 72c are formed by spraying the activated carbon particles onto a granular base material 72e or fibrous base material 72f carrying the calcium phosphate-based ceramic particles 72a.
It is carried on the granular base material 72e or the fibrous base material 72f. Examples of the material of the granular base material 72e and the fibrous base material 72f include organic polymer materials such as cellulose, polysulfone, polyamide, polyvinyl alcohol, nylon, polystyrene, polypropylene, polycarbonate and polyethylene. The base materials 72e and 72f may be porous bodies or may not be porous bodies. Except for the above
The structure of the drinking water purifier according to the present embodiment is the same as the structure of the drinking water purifier according to the first embodiment.

Also in the drinking water purifier of the present invention, as in the drinking water purifier according to the first embodiment, the drinking water is a granular base material 72e carrying calcium phosphate ceramics 72a and activated carbon particles 72c and / or. Or fibrous base material 72f
When passing through the filtration layer of and the filtration layer of the hollow fiber filtration membrane 3,
The activated carbon 72c removes chlorine odor, musty odor, etc., the calcium phosphate ceramics 72a removes lead, and the hollow fiber filtration membrane 3 removes other pollutants, microorganisms, and the like. The lead adsorption performance of the calcium phosphate ceramics 72a is maintained for a long time, and there is no possibility that a large amount of lead adsorbed on the calcium phosphate ceramics 72a will be released into tap water. Activated carbon 72c and calcium phosphate ceramics 72a are a single section 1a
Since it is filled in the inside, the size of the water purifier is smaller than that in the case where both are filled in separate compartments.

An drinking water purifier according to an eighth embodiment of the present invention will be described with reference to FIG. In this embodiment, in the first section 1a, as shown in FIG. 8 (a), granular and / or fibrous calcium phosphate-based ceramics 8 is formed on the surface.
The first section 1a is filled with a scroll-shaped laminated body 82 formed by winding a non-woven fabric-like base material 82g on which 2a and granular and / or fibrous activated carbon 82c are dispersed, or Fig. 8 (b). As shown in FIG. 2, a laminated body 82 'formed by integrally winding a sheet-like porous base material 82e carrying calcium phosphate-based ceramic particles 82a' and activated carbon particles 82c 'with a non-woven fabric-like base material 82g' is a first section. It is filled in 1a. Nonwoven fabric substrates 82g and 82g 'include non-woven fabrics such as glass fiber, plastic fiber, metal fiber and fibrous activated carbon, and the sheet-shaped porous substrate 82e includes cellulose, polysulfone, polyamide, polyvinyl alcohol, Examples include non-woven fabrics and meshes made of fibers of organic polymer materials such as nylon, polystyrene, polypropylene, polycarbonate and polyethylene. The method for supporting the calcium phosphate-based ceramic particles 82a 'on the sheet-shaped porous base material 82e is the same as in the fourth embodiment. The activated carbon particles 82c 'are
By being sprayed onto the sheet-shaped porous base material 82e,
It is carried on a sheet-shaped porous substrate 82e. Except for the above, the structure of the drinking water purifier according to the present embodiment is the same as the structure of the drinking water purifier according to the first embodiment.

Also in the drinking water purifier, the drinking water is the laminated body 8 as in the drinking water purifier according to the first embodiment.
When passing through the filtration layers 2, 82 'and the hollow fiber filtration membrane 3, the activated carbons 82c, 82c' remove chlorine odor, mold odor, etc., and the calcium phosphate ceramics 82
Lead is removed by a and 82a ', and other pollutants, microorganisms, etc. are removed by the hollow fiber filtration membrane 3. The lead adsorption performance of the calcium phosphate-based ceramics 82a, 82a 'is maintained for a long time, and there is no possibility that a large amount of lead adsorbed by the calcium phosphate-based ceramics 82a, 82a' will be released into tap water. Activated carbon 82c, 82
c'and calcium phosphate ceramics 82a, 82
Since a'and a'are filled in a single compartment 1a, the size of the water purifier is smaller than that in the case where both are filled in separate compartments.

Although the drinking water purifier according to the present invention has been described above, the present invention can of course be applied to a water purifier such as factory wastewater containing a lead component. Also, the forms of activated carbon and calcium phosphate-based ceramics are not limited to granular or fibrous forms. For example, the activated carbon formed into a lump and the calcium phosphate ceramics formed into a porous lump may be laminated. The hollow fiber filtration membrane may be removed from the above water purifier. Even if it can remove lead, chlorine odor, and musty odor, it is sufficiently useful as a water purifier. In the above embodiment, in the sixth embodiment, the surface is granular and / or
Alternatively, a nonwoven fabric 62c made of activated carbon fibers in which fibrous calcium phosphate-based ceramics 62a are scattered may be folded or stacked to form a laminated body, and a sheet-shaped porous base material carrying calcium phosphate-based ceramics particles 62a '. 62e may be integrated with the non-woven fabric 62c 'made of activated carbon fiber and folded or stacked to form a laminate. In the eighth embodiment, the surface is a granular and / or fibrous calcium phosphate-based ceramics 82.
A non-woven substrate 82g in which a and granular and / or fibrous activated carbon 82c are dispersed may be folded or stacked to form a laminate, and calcium phosphate ceramics particles 82a 'and activated carbon particles 82c' may be formed. The sheet-shaped porous base material 82e to be carried may be integrated with the non-woven cloth-shaped base material 82g 'to be folded or stacked to form a laminate.

(2) Effect confirmation test The effect of the present invention was confirmed by a test. Lead Elution Test 1 As shown in FIG. 9, a beaker 10 filled with lead-containing water
1, a tubing pump 102, a pressure gauge 103,
The device A was constituted by the column 104 and the pipe line 105 connecting these. The particle size is 10 in column 104
The activated carbon particles are filled with activated carbon particles of 0 to 150 μm, and the lead-containing water is circulated while maintaining the water pressure in the pipe 105 and thus the flow rate in the pipe 105 at a predetermined value, and the activated carbon particles have about 10 mg / min.
g lead was adsorbed. As shown in FIG. 10, a beaker 106 filled with tap water, a heater 107 for heating the tap water in the beaker 106, a thermometer 108 for measuring the temperature of the tap water in the beaker 106, and a tubing pump 109. , Pressure gauge 110, column 111, and test tube 1
The apparatus B was constituted by 12 and the conduit 113 connecting these. Column 1 of device A, column 1 of device B
About 2.5 g of activated carbon particles adsorbing about 10 mg / g of lead taken out from No. 04 were filled, and the water pressure in the pipe 113, and consequently the space velocity in the pipe 113 (the volume velocity of the fluid in the apparent volume of the packed bed While keeping the divided value) at a predetermined value exceeding 400 / hour, the beaker 106 outputs a predetermined temperature (20
℃, 40 ℃, 60 ℃, 80 ℃) heated to 10μg /
Tap water containing lead at a concentration of dm ³ or less was introduced into the column 111 of the apparatus B, and activated carbon particles adsorbing about 10 mg / g of lead were permeated and then collected by the test tube 112. The lead concentration in tap water collected in the test tube 112 was measured by potentiometric stripping analysis. Table 1 shows the test conditions for the lead elution test using the apparatus B. The result of the lead elution test using the device B is shown in FIG.

[0023]

[Table 1]

From Table 1 and FIG. 11, when activated water particles adsorbing about 10 mg / g of lead were supplied with tap water containing lead at a concentration of 10 μg / dm ³ or less at 20 ° C. to 80 ° C., the activated carbon particles were removed. Concentration of 1 mg / dm ³ or more (1 in the tap water
It can be seen that hot water containing lead comes out at a concentration of 00 times or more). It is also found that the amount of lead eluted is large when hot water is poured.

Lead Elution Test 2 Using the devices A and B of the lead elution test 1, the amount of lead adsorbed on the activated carbon particles was set to 0.38 mg / g, and the beaker 10 was used.
The lead elution test was performed by limiting the temperature of tap water in 6 to 20 ° C. and 80 ° C. and setting the other test conditions to be substantially the same as the lead elution test 1. Table 2 shows the test conditions of the lead elution test, and FIG. 12 shows the result of the lead elution test.

[0026]

[Table 2]

From Table 2 and FIG. 12, when activated water particles having 0.38 mg / g of lead adsorbed thereto were fed with tap water containing lead at a concentration of 1.5 μg / dm ³ at 20 ° C. It was found that hot water containing lead was emitted at a concentration about 10 times that of tap water, and activated carbon particles adsorbed 0.38 mg / g of lead contained lead at a concentration of 2.35 μg / dm ^3. It can be seen that when running tap water at 80 ° C., hot water containing lead at a concentration about 15 times that of the tap water comes out from the activated carbon.

Lead Elution Test 3 Using the apparatus A of the Lead Elution Test 1, in the same manner as in the Lead Elution Test 1, activated carbon particles having a particle size of 100 to 150 μm were mixed with about 9
mg / g of lead was adsorbed. Using the device B of the lead elution test 1, the above-mentioned activated carbon particles having adsorbed about 9 mg / g of lead were packed in the column 111 of the device B, and as shown in FIG. A column 114 filled with apatite particles was arranged below the column 111 and connected to the column 111 in series. Similarly to the lead elution test 1, 80 ° C. tap water containing lead at a concentration of about 10 μg / dm ³ was introduced from the beaker 106 of the apparatus B to the column 111, and activated carbon particles having about 9 mg / g of lead adsorbed thereon were collected. Transparent. The tap water that had permeated the activated carbon particles was guided to a column 114 further filled with hydroxyapatite particles, and after permeating the hydroxyapatite particles, it was collected by a test tube 112. The lead concentration in the warm water collected in the test tube 112 was measured by potentiometric stripping analysis. Table 3 shows the test conditions for the lead dissolution test, and Fig. 1 shows the results of the lead dissolution test.
4 shows.

[0029]

[Table 3]

From Table 3 and FIG. 14, it can be seen that the lead concentration of the hot water collected in the test tube 112 is reduced to 1/2 to 1/5 of the lead concentration of the tap water in the beaker 106. By comparing with the result of the lead elution test 1, it can be seen that the high concentration lead eluted from the activated carbon into the high temperature water is adsorbed on the hydroxyapatite.

Lead Elution Test 4 Using the apparatus A of the Lead Elution Test 1, in the same manner as in the Lead Elution Test 1, activated carbon particles having a particle size of 100 to 150 μm, activated carbon particles and hydroxyapatite particles are 1: 1. To a mixture of activated carbon particles and tricalcium phosphate particles in a volume ratio of 1: 1 and a mixture of activated carbon particles and bone charcoal particles in a volume ratio of 1: 1, respectively. 0.3-0.4 mg / g of lead was adsorbed. Using the device B of the lead elution test 1, about 0.3 to 0.4 mg / g described above
The column 111 of the apparatus B was filled with the activated carbon particles having adsorbed lead, the mixture of activated carbon particles and hydroxyapatite particles, the mixture of activated carbon particles and tertiary calcium phosphate particles, and the mixture of activated carbon particles and bone carbon particles, respectively. . Lead elution test 1
Similarly, from the beaker 106 of the device B, about 1.0 to
80 ° C. tap water containing lead at a concentration of 5.0 μg / dm ³ was introduced into the column 111, and about 0.3 to 0.4 mg / g of lead adsorbed activated carbon particles, activated carbon particles and hydroxyapatite particles were obtained. Of water, a mixture of activated carbon particles and tricalcium phosphate particles, and a mixture of activated carbon particles and bone charcoal particles were permeated. The test tube 112 collected hot water that passed through the activated carbon particles, the mixture of activated carbon particles and hydroxyapatite particles, the mixture of activated carbon particles and tricalcium phosphate particles, and the mixture of activated carbon particles and bone carbon particles. The lead concentration in the warm water collected in the test tube 112 was measured by potentiometric stripping analysis. The test conditions of the lead elution test are shown in Table 4, and the results of the lead elution test are shown in FIGS.

[0032]

[Table 4]

From FIGS. 15 and 16, hydroxyapatite particles,
By mixing the third calcium phosphate particles and bone charcoal particles with the activated carbon particles, the lead concentration in the permeated water is reduced to about 1/100 as compared with the case where only the activated carbon particles are used, and the lead elution rate (per the predetermined amount It can be seen that the cumulative weight fraction of lead eluted into the permeated water with respect to lead adsorbed on the activated carbon is reduced to about 1/15 to 1/80. From FIGS. 15 and 16, by mixing the hydroxyapatite particles, the third calcium phosphate particles, and the bone charcoal particles with the activated carbon particles, it is possible to prevent the lead adsorbed by the activated carbon from being eluted into the high temperature water and discharged from the water purifier. I understand. Further, it can be seen that, among the calcium phosphate-based ceramics, the bone charcoal particles show particularly excellent lead removal performance.

Water Flow Test Using Commercially Available Drinking Water Water Purifier When a commercially available drinking water water purifier is used and the activated carbon storage compartment of the water purifier is filled with only bone charcoal, activated carbon and bone charcoal are 1
When the mixture mixed in a volume ratio of 1: 1 was filled, when the mixture in which activated carbon and bone charcoal were mixed in a volume ratio of 3: 1 was filled, the mixture in which activated carbon and bone charcoal were mixed in a volume ratio of 9: 1 was used. In the case of filling, when the mixture of activated carbon and bone charcoal was mixed at a volume ratio of 99: 1, and in the case of filling only activated carbon, tap water with a lead concentration of 50 μg / dm ³ was used. 500 per day at a flow rate of 2 dm ³ / min
dm ³ After passing water through the water purifier, stopping water passage and leaving it for one day and night was repeated 4 times, and a water passage test with a total flow rate of 2000 dm ³ was conducted. At the time of water flow, at the start of water flow (first running water)
Then, the average lead concentration in the permeate that passed through the water purifier was measured by potentiometric stripping analysis every 100 dm ^{3 of} water flow rate. Figure 1 shows the results of the water flow test
7 shows. From FIG. 17, when the activated carbon storage compartment of the water purifier is filled with only activated carbon, the lead removal performance of the water purifier sharply decreases with time, and after a predetermined period has elapsed, as shown by the arrow in FIG. It can be seen that at the start of water flow, the lead adsorbed on the activated carbon is eluted into the permeate, and the lead concentration in the permeate becomes higher than the lead concentration in the raw tap water before passing through the water purifier.
As shown by the arrow in FIG. 17, when the activated carbon storage compartment of the water purifier was filled with a mixture of activated carbon and bone charcoal having a proportion of bone charcoal of 1% by volume or more, the lead adsorbed on the active end at the start of water flow was It does not elute in the permeate and the lead concentration in the permeate does not become higher than the lead concentration in the raw tap water before passing through the water purifier. From FIG. 17, when the activated carbon storage compartment of the water purifier is filled with a mixture of activated carbon and bone charcoal in which the proportion of bone charcoal is 25% by volume or more, there is no possibility that the lead removal performance of the water purifier will deteriorate sharply over time. It can be seen that the lead removal performance of the water purifier is maintained over a long period of time.

[0035]

As described above, in the present invention, chlorine odor, musty odor, etc. are removed by activated carbon, and lead is removed by calcium phosphate ceramics. There is no possibility that the lead adsorption performance of the calcium phosphate-based ceramics will deteriorate sharply with time. Further, there is no possibility that a large amount of lead adsorbed on the calcium phosphate-based ceramic will be released into tap water. Even if the lead adsorbed on the activated carbon is released into the water, the lead is adsorbed on the calcium phosphate ceramics filled in the same compartment as the activated carbon, so a large amount of lead is released into the permeated water discharged from the water purifier. There is no fear of being. Therefore, the present invention provides a water purifier that removes chlorine odors, musty odors, etc., does not have a possibility that lead adsorption performance may sharply decrease with time, and does not release a large amount of adsorbed lead into tap water. . By using bone charcoal as the calcium phosphate ceramics, a water purifier having particularly excellent lead removal performance can be obtained. By setting the volume% of calcium phosphate ceramics to the sum of activated carbon and calcium phosphate ceramics to be 1% or more, the lead adsorbed on the activated carbon at the start of water passage is eluted into the permeate and the lead concentration in the permeate is There is no risk of becoming higher than the lead concentration in the raw water before passing through the water purifier. By setting the volume% of calcium phosphate-based ceramics to the sum of activated carbon and calcium phosphate-based ceramics to 25% or more, it is possible to prevent the situation where the lead removal performance of the water purifier sharply deteriorates and to improve the lead removal performance of the water purifier. It can be maintained for a long time. By packing the activated carbon and the calcium phosphate-based ceramics in a single compartment, the size of the water purifier can be made smaller than that in the case where both are packed in separate compartments. Activated carbon and calcium phosphate ceramics
The compartment needs to be filled in a manner that allows water to pass through. When the granular and / or fibrous activated carbon and the granular and / or fibrous calcium phosphate ceramics are filled in the compartment, water can pass through the activated carbon and the calcium phosphate ceramics. Any mode may be used for filling the compartments with granular and / or fibrous activated carbon and granular and / or fibrous calcium phosphate ceramics. Granular and / or fibrous activated carbon and granular and / or fibrous calcium phosphate-based ceramics may be mixed and filled in the compartment, and the granular and / or fibrous activated carbon carrying calcium phosphate-based ceramic particles Granules and / or fibrous calcium phosphate-based ceramics that carry activated carbon particles may be filled in the compartments, and the compartments may be filled with granular and / or fibrous base materials that carry calcium phosphate-based ceramic particles. May be mixed with granular and / or fibrous activated carbon to fill the compartment, and a granular and / or fibrous base material carrying activated carbon particles and a granular and / or fibrous calcium phosphate ceramics The mixture may be mixed and filled in the compartment, and a granular and / or fibrous layer of activated carbon and a granular and / or fibrous calcium phosphate A laminate having a layer of the system ceramics may be filled in the compartment. The laminated body may be formed by winding a nonwoven fabric of activated carbon fibers in which granular and / or fibrous calcium phosphate-based ceramics are scattered on the surface, and a sheet-like porous base material carrying calcium phosphate-based ceramic particles is formed. It may be formed by being integrally wound with a non-woven fabric of activated carbon fiber. Further, the compartment may be filled with a granular and / or fibrous base material carrying activated carbon particles and calcium phosphate-based ceramic particles, and the surface may have granular and / or fibrous activated carbon and granular and / or fibrous base materials. The compartment may be filled with a roll-shaped laminate formed by winding a non-woven fabric-like substrate on which calcium phosphate-based ceramics are sprinkled, and a sheet-like porous material carrying activated carbon particles and calcium phosphate-based ceramics particles. The compartment may be filled with a roll-shaped laminate formed by winding the base material integrally with the non-woven base material. In any of the above cases, the size of the water purifier can be reduced as compared with the case where activated carbon and calcium phosphate-based ceramics are filled in separate compartments. When the water purifier is a water purifier for drinking water, the compact water purifier for drinking water removes chlorine odors, musty odors, and the like from tap water that is drinking water, and also removes lead. There is no fear that the lead adsorption performance of the drinking water purifier will suddenly decrease over time, and there is also no risk that a large amount of lead will be released from the drinking water purifier into tap water.

[Brief description of drawings]

FIG. 1 is a structural diagram of a drinking water purifier according to a first embodiment of the present invention. (A) is a side section, (b) is a bb arrow view of (a).

FIG. 2 is a diagram showing an embodiment of activated carbon and calcium phosphate-based ceramics filled in a first section of a drinking water purifier according to a second embodiment of the present invention.

FIG. 3 is a diagram showing an embodiment of activated carbon and calcium phosphate-based ceramics filled in a first compartment of a drinking water purifier according to a third embodiment of the present invention.

FIG. 4 is a diagram showing an embodiment of activated carbon and calcium phosphate-based ceramics filled in a first compartment of a drinking water purifier according to a fourth embodiment of the present invention.

FIG. 5 is a diagram showing an embodiment of activated carbon and calcium phosphate-based ceramics filled in a first compartment of a drinking water purifier according to a fifth embodiment of the present invention.

FIG. 6 is a diagram showing an embodiment of activated carbon and calcium phosphate-based ceramics filled in the first section of the drinking water purifier according to the sixth embodiment of the present invention.

FIG. 7 is a diagram showing an embodiment of activated carbon and calcium phosphate-based ceramics filled in a first compartment of a drinking water purifier according to a seventh embodiment of the present invention.

FIG. 8 is a diagram showing an embodiment of activated carbon and calcium phosphate-based ceramics filled in a first compartment of a drinking water purifier according to an eighth embodiment of the present invention.

FIG. 9 is a diagram showing a configuration of a test device used in a lead elution test performed to confirm the effect of the present invention.

FIG. 10 is a diagram showing a configuration of a test apparatus used in a lead elution test performed to confirm the effect of the present invention.

FIG. 11 is a diagram showing the results of a lead elution test 1 conducted to confirm the effect of the present invention.

FIG. 12 is a diagram showing the results of a lead elution test 2 performed to confirm the effects of the present invention.

FIG. 13 is a diagram showing a part of the configuration of an apparatus used in a lead elution test 3 carried out to confirm the effect of the present invention.

FIG. 14 is a diagram showing the results of a lead elution test 3 performed to confirm the effects of the present invention.

FIG. 15 is a diagram showing the results of a lead elution test 4 performed to confirm the effects of the present invention.

FIG. 16 is a diagram showing the results of a lead elution test 4 performed to confirm the effects of the present invention.

FIG. 17 is a diagram showing the results of a water flow test using a commercially available water purifier for drinking water, which was performed to confirm the effects of the present invention.

[Explanation of symbols]

1 Case 1a 1st division 1b 2nd division 2 Mixture of activated carbon and calcium phosphate type ceramics 3 Hollow fiber filtration membrane 4 Porous partition plate 5 End plate 6 Porous partition plate 22a, 32a, 42a, 52a, 72a Granular Calcium phosphate type ceramics 22c, 32c, 42c, 52c, 72c Granular activated carbon 22d, 42d Fibrous activated carbon 32b, 52b Fibrous calcium phosphate type ceramics 42e, 52e, 72e Granular base material 42f, 52f, 72f Fibrous base material 62a Granular and / or fibrous calcium phosphate ceramics 62c Non-woven fabric of activated carbon fiber 62 Laminated body 62a 'Granular calcium phosphate ceramics 62c' Non-woven fabric of activated carbon fiber 62e Sheet-like porous substrate 62 'Laminated body 82 Laminated body 82a Granular and / Or Fibrous calcium phosphate-based ceramics 82c Granular and / or fibrous activated carbon 82g Nonwoven substrate 82 'Laminate 82a' Granular calcium phosphate ceramics 82c 'Granular activated carbon 82e Sheet-like porous substrate 82g' Nonwoven Substrate 104, 111, 114 Column A, B tester

Front page continuation (72) Inventor Etsuko Kawamura 2-1-1 Nakajima, Kokurakita-ku, Kitakyushu City Tohoku Kikai Co., Ltd. (72) Inventor Satoshi Kitazaki 2-1-1 Nakajima, Kokurakita-ku, Kitakyushu Equipment Co., Ltd. (72) Inventor Takuo Imasaka 2-1-1, Nakajima, Kokurakita-ku, Kitakyushu City Totoki Equipment Co., Ltd.

Claims (18)

[Claims] 1. A water purifier comprising a compartment filled with activated carbon and calcium phosphate ceramics. 2. The water purifier according to claim 1, wherein the calcium phosphate ceramics is bone charcoal. 3. The water purifier according to claim 1, wherein the volume% of the calcium phosphate ceramics with respect to the sum of the activated carbon and the calcium phosphate ceramics is 1% or more and less than 25%. 4. The water purifier according to claim 1, wherein the volume percentage of the calcium phosphate ceramics with respect to the sum of the activated carbon and the calcium phosphate ceramics is 25% or more. 5. The granular and / or fibrous activated carbon and the granular and / or fibrous calcium phosphate-based ceramics are filled in the compartments according to any one of claims 1 to 4. Water purifier as described. 6. The granular and / or fibrous activated carbon and the granular and / or fibrous calcium phosphate-based ceramics are mixed and filled in the compartment. The water purifier according to item 1. 7. The water purifier according to claim 1, wherein the compartments are filled with granular and / or fibrous activated carbon carrying calcium phosphate-based ceramic particles. 8. The water purifier according to claim 1, wherein the compartments are filled with granular and / or fibrous calcium phosphate-based ceramics carrying activated carbon particles. 9. The granular and / or fibrous base material carrying the calcium phosphate ceramics particles and the granular and / or fibrous activated carbon are mixed and filled in the compartment. The water purifier according to any one of 1 to 4. 10. The granular and / or fibrous base material carrying activated carbon particles and the granular and / or fibrous calcium phosphate ceramics are mixed and filled in the compartment. The water purifier according to any one of 1 to 4. 11. The compartment is filled with a laminate having a layer of granular and / or fibrous activated carbon and a layer of granular and / or fibrous calcium phosphate ceramics in the compartment. The water purifier according to any one of 4 above. 12. The water purifier according to claim 11, wherein the laminate is formed by winding a non-woven fabric of activated carbon fibers on the surface of which granular and / or fibrous calcium phosphate-based ceramics are dispersed. . 13. The purified water according to claim 11, wherein the laminated body is formed by integrally winding a sheet-like porous base material carrying calcium phosphate-based ceramic particles with a nonwoven fabric of activated carbon fibers. vessel. 14. The partition is filled with a granular and / or fibrous base material carrying activated carbon particles and calcium phosphate-based ceramic particles.
The water purifier according to any one of 1 to 4. 15. The compartment is filled with a laminated body formed by laminating layers containing granular and / or fibrous activated carbon and granular and / or fibrous calcium phosphate-based ceramics. One of claims 1 to 4.
Water purifier according to item. 16. The laminate is formed by winding a non-woven fabric-like base material on the surface of which granular and / or fibrous activated carbon and granular and / or fibrous calcium phosphate ceramics are dispersed. Claim 1
The water purifier according to 5. 17. The laminate is formed by integrally winding a sheet-like porous base material carrying activated carbon particles and calcium phosphate-based ceramic particles together with a non-woven fabric-like base material. The water purifier according to 15. 18. A water purifier for drinking water according to any one of claims 1 to 17.