JP5147021B2 - Water purifier - Google Patents

Description

  The present invention relates to a water purifier that purifies tap water (raw water) and flows out as purified water, and more particularly to a water purifier that uses a hollow fiber membrane as a filter medium.

Tap water may contain various particulate impurities such as red rust and other turbid components, residual chlorine, agricultural chemicals, lead and other harmful components.
It may also contain trihalomethane produced by the reaction of chlorine and organic substances in tap water.

Thus, conventionally, tap water is generally used after being purified through a water purifier.
Tap water (raw water) is passed through a filter medium inside the water purifier, where it is purified by the filtering action of the filter medium and then flows out of the water purifier.

Conventionally, many such water purifiers use a hollow fiber membrane filter as a filter medium, and are usually used in combination with granular activated carbon.
The hollow fiber membrane has an infinite number of micropores, and tap water can pass through these micropores from the outside to the inside, and the turbid components contained in the tap water are filtered at this time. Removed from tap water.
The micropores of the hollow fiber membrane are extremely small, and turbid components such as impurities contained in tap water can be removed up to the hollow fiber membrane up to about 0.1 μm.

On the other hand, a water purifier using a ceramic filter made of a porous ceramic sintered body as a filter medium is also conventionally known.
For example, Patent Document 1 below discloses this type of water purifier.
This ceramic filter also has a large number of micropores, and when tap water passes through the micropores, turbid components contained in tap water are filtered and removed from the tap water.

However, the fine pores of the porous ceramic filter are relatively larger than the fine pores of the hollow fiber membrane, and with such a ceramic filter, turbid components having a size of up to about 0.5 μm can be removed.
As long as the water quality level of the original tap water is normal, tap water can be sufficiently purified even with a water purifier using this ceramic filter as a filter medium.

  However, humic acid, which is a turbid component in tap water overseas, etc. (humic acid is an amorphous polymer substance that is a final product obtained by decomposition of plants etc. by microorganisms, etc.) There is a low water quality level that contains a lot of flocs of flocculant (aluminum flocculant derived from polyaluminum chloride added as flocculant) added to settle suspended particles in water in the field, In this case, in the case of the water purifier using the above-described hollow fiber membrane filter as a filter medium, these components can be sufficiently removed to a fine one and the purification performance is high, while the hollow fiber membrane is clogged early. Therefore, there is a problem that the service life is reached immediately, that is, the clogging durability is low.

  On the other hand, in the case of a water purifier using a ceramic filter made of a porous ceramic sintered body, the pore size of the filter is relatively larger than that of the hollow fiber membrane filter, and the size of the turbid component removed from tap water is 0. Since the thickness is about 5 μm or more, the clogging durability is relatively better than that using a hollow fiber membrane filter.

However, many turbid components such as humic acid contained in tap water with a low water quality are smaller than 0.5 μm. Therefore, in a water purifier using such a ceramic filter, a turbid component smaller than 0.5 μm is sufficient. Therefore, there is a problem that the purification performance is not sufficient.
That is, neither a filter using a hollow fiber membrane filter nor a filter using a ceramic filter is sufficient to ensure high purification performance and good clogging durability.

In addition, the following patent document 2, patent document 3, and patent document 4 are made | formed regarding the water purifier which used the hollow fiber membrane filter as a filter medium.
However, all of those disclosed in Patent Documents 2, 3 and 4 are a combination of granular activated carbon and a hollow fiber membrane filter, or a combination of granular activated carbon and activated carbon fiber and a hollow fiber membrane, There is no disclosure of a combination of a hollow fiber membrane filter and a ceramic filter.

JP 2007-167742 A JP-A-11-333446 Japanese Patent Laid-Open No. 10-174969 JP 2002-263639 A

  The present invention has been made for the purpose of providing a water purifier having good clogging durability while ensuring high purification performance against the background described above.

Thus, according to the first aspect of the present invention, in the water purifier in which the raw water flowing in from the raw water inlet is passed through the filter medium to be purified by the filtering action of the filter medium, and the purified water is discharged from the purified water outlet, a ceramic filter consisting of sintered body, and the hollow fiber membrane filter, and grain-like activated carbon layer, and an active carbon fiber layer, from the upstream side to the downstream side of the flow, the granular activated carbon layer, the active carbon fiber layer, a ceramic filter, What is arranged in the order of the hollow fiber membrane filter tare, the outer periphery of a bottomed cylindrical case inside the filling space, the granular activated carbon layer along the axial direction of the case provided in section donut ring, from the raw water inlet The raw water that has flowed in flows into the granular activated carbon layer from the open end side in the axial direction of the granular activated carbon layer, and flows through the granular activated carbon layer in the axial direction. The activated carbon fiber layer arranged in a cylindrical shape inside the cylinder through the water-permeable holes provided on the inner side of the granular activated carbon layer and the inner side of the granular activated carbon layer, and arranged in the central part further inside the activated carbon fiber layer the tubular through the ceramic filter in the radially inward direction, respectively, and then passed through the hollow fiber membrane filter disposed inwardly of and the granular activated carbon layer on the open end side than the ceramic filter, the water purification It is characterized by flowing out from the outlet.

According to a second aspect of the present invention, in the first aspect, the cross-sectional area of the granular activated carbon layer is ³ to 80 cm ² and the filling volume is 100 to 1000 cm ^3. A water purifier having a ratio cross-sectional area (cm ² ) / axial length (cm) of 1.0 to 3.0.

Effects and effects of the invention

As described above, the present invention uses a ceramic filter composed of a porous ceramic sintered body as a filter medium for a water purifier and a hollow fiber membrane filter, and the hollow fiber membrane filter is disposed upstream of the ceramic filter. Is arranged on the downstream side of the flow.
In the water purifier of the present invention, the turbid component contained in tap water is first filtered through a ceramic filter, and the material that has passed through the ceramic filter is filtered and removed through a hollow fiber membrane filter.

Of the above two types of filters, in the case of a water purifier using a hollow fiber membrane filter alone without using a ceramic filter, relatively large turbid components that can be removed with a ceramic filter are filtered and removed with the hollow fiber membrane filter alone. This will increase the load on the hollow fiber membrane filter.
That is, a fine turbid component to a large turbid component are filtered by the hollow fiber membrane filter, the clogging of the hollow fiber membrane filter becomes remarkable, and the hollow fiber membrane filter reaches the service life at an early stage. That is, the endurance life is reached.

However, in the present invention, the ceramic filter performs a filtering action before the hollow fiber membrane filter to remove turbid components in the tap water, specifically, clogging substances to the filter. Therefore, only the clogging substances that have passed through the ceramic filter are hollow. It reaches the thread membrane filter, where it is removed by filtration at the hollow fiber membrane filter.
As a result, the load on the hollow fiber membrane filter is reduced, the clogging of the hollow fiber membrane filter is suppressed, and the service life of the water purifier, that is, the clogging durability life is effectively increased.

  On the other hand, in the case of the water purifier of the present invention, the ceramic filter and the hollow fiber membrane filter share and perform a filtering action, so that a relatively coarse clogging substance to a fine clogging substance can be satisfactorily removed with these filters. And high purification performance for tap water can be ensured.

  For example, humic acid has a relatively large floc form that can be removed by a ceramic filter, and a fine floc form that cannot be removed by a ceramic filter, for example, a fine one smaller than 0.5 μm, is tap water. In this case, the entire humic acid cannot be removed with the ceramic filter alone, whereas the entire humic acid can be removed with the hollow fiber membrane filter alone, but the load on the hollow fiber membrane filter is excessive. Thus, the hollow fiber membrane filter is clogged early.

In the present invention, these ceramic filters and the hollow fiber membrane filter are assigned roles, so that the durability of the water purifier can be effectively extended while ensuring high purification performance.
Here, the ceramic filter can be configured in a form in which a layer of diatomaceous earth is integrally laminated on the upstream surface of the flow.

In the present invention, Ri Contact further comprising a granular activated carbon layer and the active carbon fiber layer as a filter medium, to remove organic matter other turbid components of humic acid is a clogging caused material (turbidity particles) by filtration and adsorption In addition, residual chlorine, trihalomethane, agricultural chemicals and other harmful components dissolved in tap water can be removed by adsorption, and the purification performance of the water purifier can be further enhanced.

In this case, the granular activated carbon layer from the upstream side to the downstream side of the flow, the active carbon fiber layer, a ceramic filter, Contact Ku arranged in the order of the hollow fiber membrane filter.

The granular activated carbon layer and the activated carbon fiber layer also have a function of filtering particles of coarse turbid components.
Of these, the granular activated carbon layer can filter visible large particles, while the activated carbon fiber layer can filter smaller particles.

Therefore, by placing these granular activated carbon layer and activated carbon fiber layer upstream of the ceramic filter and the granular activated carbon layer further upstream of the activated carbon fiber layer, the turbidity component can be increased from small to large. And can be efficiently removed from tap water.
As a result, the amount of turbid components to be removed by the hollow fiber membrane filter, the ceramic filter, and the activated carbon fiber layer is reduced, the load on them is reduced, and the clogging durability life of the entire water purifier is extended.

In the present invention, to our Ku constituting the water purifier in the following structure.
That is, a granular activated carbon layer is provided in a cross-sectional donut shape along the axial direction of the case on the outer peripheral side of the filling space inside the bottomed cylindrical case, and the raw water flowing from the raw water inlet is opened in the axial direction of the granular activated carbon layer. After flowing into the granular activated carbon layer from the side and moving the inside of the granular activated carbon layer in the axial direction, through the water permeability holes of the cylindrical body provided on the bottom side in the axial direction of the filling space and on the inner peripheral side of the granular activated carbon layer , Activated carbon fiber layer arranged in a cylindrical shape inside the cylinder, passed through a cylindrical ceramic filter arranged in the central part further inside the activated carbon fiber layer in the radial direction, and then the bottom portion with respect to the ceramic filter is passed through a hollow fiber membrane filter disposed on the inside of and granular activated carbon layer on the side opposite to the, form a structure in which flow out from the water purifier outlet Contact Ku.
By doing so, it is possible to purify the tap water by sequentially passing the tap water through the granular activated carbon layer, the activated carbon fiber layer, the ceramic filter, and the hollow fiber membrane filter while configuring the water purifier compactly.

In yet present invention can be allowed to comprise an antibacterial ceramic filter comprising ceramic sintered body of the porous.
For example, as in the water purifier disclosed in Patent Document 1, when a granular activated carbon layer is provided on the upstream side of the flow with respect to the ceramic filter, germs propagate in the granular activated carbon layer and the remaining water remaining on the downstream side. The slime (carcasses and metabolites, etc.) of bacteria can become clogging substances and adhere to the ceramic filter and the hollow fiber membrane filter on the downstream side, and the ceramic filter and hollow fiber membrane filter. It will promote clogging.

However, if this is done , the antibacterial action of the ceramics filter suppresses the propagation of germs in the ceramics filter and the surrounding area, resulting in the propagation of germs in the ceramics filter and the hollow fiber membrane filter downstream thereof. Therefore, it is possible to prevent a problem that the slime substance adheres and promotes clogging, and the clogging durability of the ceramic filter and the hollow fiber membrane filter can be improved.

In the present invention, it is possible to keep the powder formed by grinding a ceramic having antibacterial properties in the accommodating space of the hollow fiber membrane filter, accommodated in conjunction with the hollow fiber membrane filter.
In this way, it is possible to more effectively prevent the propagation of germs on the hollow fiber membrane filter, and it is even more effective for the slime substances produced by the propagation of germs to adhere to the hollow fiber membrane filter. Therefore, the clogging durability of the hollow fiber membrane filter can be further effectively increased.

As powder of Naoko, it is possible to use a material obtained by pulverizing the above ceramic filter. However, an antibacterial ceramic different from the ceramic filter may be pulverized to obtain the above powder.
In these cases, the powder can be dispersedly attached to the wall surface of the hollow fiber membrane.

In the present invention, Ru can keep receiving the powder having the antimicrobial in the housing space of the granular activated carbon layer.
If it does in this way, antibacterial property can be provided also to a granular activated carbon layer, and generation | occurrence | production of the slime substance as a clogging substance by the propagation of miscellaneous bacteria and bacteria propagation in a granular activated carbon layer can be prevented thru | or suppressed.

In this case, the powder can be stored in a mixed state with granular activated carbon.
This powder can be stored in both the storage space of the hollow fiber membrane and the storage space of the granular activated carbon layer.
This powder can also be stored in the storage space of the activated carbon fiber layer.

In particular, if the above-mentioned powder having antibacterial properties is accommodated in any of the housing space for the hollow fiber membrane, the housing space for the granular activated carbon layer, and the housing space for the activated carbon fiber layer, the entire interior of the water purifier is antimicrobial. State.
In addition, about the activated carbon fiber layer, the antibacterial agents, such as silver, can be couple | bonded by the stage of the shaping | molding by the case, and accommodation of the said powder in an activated carbon fiber layer can be omitted in this case.

In a water purifier using a granular activated carbon layer as a filter medium, a general household one usually has a filling volume of 100 to 1000 cm ³ .
Accordingly, in claim 2 , the filling volume of the granular activated carbon layer is set to 100 to 1000 cm ³ .
In addition, in this second aspect, the cross-sectional area of the cross section of the granular activated carbon layer is set to ³ to 80 cm ² , and the ratio of the cross-sectional area / axial length is set in the range of 1.0 to 3.0.
By doing in this way, the high purification performance with respect to the stain | pollution | contamination component in tap water by a granular activated carbon layer and the high clogging prevention performance in a hollow fiber membrane filter can be balanced well.

It is the figure which showed one usage example of the water purifier of one Embodiment of this invention. It is sectional drawing which showed the internal structure of the water purifier of FIG. It is the figure which showed the antibacterial effect of the ceramic particle in the accommodation space of a hollow fiber membrane filter. It is the figure which showed the improvement effect of the clogging durability by the antibacterial effect of the ceramic particle in the accommodation space of a hollow fiber membrane filter. It is the figure which showed the shape effect of the granular activated carbon layer.

Next, embodiments of the present invention will be described in detail below with reference to the drawings.
In FIG. 1, 1 is a sink installed in the kitchen, 2 is a cabinet, 3 is a sink, 10 is a counter, and 11 is an automatic faucet installed on the sink 1 and having a purified water discharge function.
The automatic faucet 11 includes a base body 12 provided in a form standing from the counter 10 and a water discharge pipe 14 extending from the body 12.
Here, the water discharge pipe 14 is rotatable by a predetermined angle with respect to the main body 12.

The main body 12 is provided with a single lever 16 at a position eccentric to the right side of the water discharge pipe 14 in a front view as viewed from the user. Here, the single lever 16 adjusts the flow rate and temperature of the discharged water.
Specifically, the temperature of the water discharge is adjusted by rotating the single lever 16 in the horizontal direction in the drawing, and the flow rate is adjusted by rotating the single lever 16 up and down.

As shown in FIG. 1, the water discharge pipe 14 has a substantially U-shaped gooseneck shape, and has a shape curved downward from a substantially intermediate portion in the tube axis direction to the distal end portion.
As shown in the figure, the water discharge pipe 14 has a water discharge port 18 at the tip, a water discharge head 22 that can be pulled out together with the flexible hose 20, and a water discharge head holder that holds the water discharge head 22 in the storage position. And a water discharge pipe main body 24 having the function as described above.

The main body portion 12 is connected to the upper ends of the water supply passage 26 and the hot water supply passage 28, and water and hot water are supplied to the main body portion 12 through the water supply passage 26 and the hot water supply passage 28.
A mixing valve (not shown) is incorporated in the main body 12, and an outflow path 32 extends from the mixing valve. Through the outflow path 32, temperature control water (by mixing the single lever 16, In some cases, the temperature control water in which water and hot water are mixed at a predetermined ratio may consist of only water or hot water (hereinafter referred to as raw water).

The hose 20 has an outflow path 32 formed inside thereof. A raw water valve (electromagnetic valve) 34 for opening and closing the outlet passage 32 is provided on the outflow passage 32. Here, the operation of the raw water valve 34 is controlled by a controller (not shown).
Further, a water purification path 38 branches out from the water supply path 26 and extends, and the tip of the water purification path 38 is connected to the outflow path 32 at the downstream portion of the raw water valve 34.

A water purifier 40 (electromagnetic valve) 42 for opening and closing the water purifier 40 and the water purifying path 38 is provided on the water purifying path 38. The operation of the water purification valve 42 is also controlled by a controller.
In addition, 46 is a water stop cock.

As shown in FIG. 1, the raw water sensor 60 and the water purification sensor 58 are provided on the upper surface of the distal end portion of the water discharge pipe 14, specifically, on the upper surface of the uppermost portion of the substantially intermediate portion in the tube axis direction of the water discharge pipe 14. Are arranged side by side in the pipe axis direction.
Here, the raw water sensor 60 is an alternate sensor that alternately discharges raw water (temperature-controlled water) from the water outlet 18 and stops the water every time the inserted hand is detected.

Specifically, when the hand is held over the raw water sensor 60, the raw water sensor 60 detects the hand in a non-contact manner, discharges the raw water from the spout 18 based on the detection, and then the raw water sensor 60 removes the hand. The raw water continues to be discharged even if the water is drawn.
Then, when the raw water sensor 60 is operated again by extending the hand, that is, when the raw water sensor 60 detects the hand, the discharge of the raw water from the spout 18 is stopped.
The water purification sensor 58 also alternately discharges purified water from the water outlet 18 and stops water discharge (stops water) every time a hand is detected (every human body is detected).
In this embodiment, the raw water sensor 60 is disposed on the front side and the lower side near the user, and the water purification sensor 58 is disposed on the far side and the upper side farther than the raw water sensor 60.

  In FIG. 1, reference numeral 41 denotes a metal bracket that holds the water purifier 40 inside the cabinet 2 and fixes it to the inner surface of the side wall 43 of the cabinet 2.

Each of the hoses 38A and 38B forms a part of the water purification path 38 therein. Specifically, the hose 38A guides the inflow path for allowing the raw water to flow into the water purifier 40 in the water purification path 38, and the hose 38B guides the purified water after being purified by the water purifier 40 to the spout 18 side. It forms an outlet for purified water.
As shown in FIG. 1, the pair of hoses 38 </ b> A and 38 </ b> B are fixed to the inner surface of the side wall portion 43 of the cabinet by a fixing portion 52.

FIG. 2 specifically shows the internal structure of the water purifier 40.
Reference numeral 62 in the figure denotes a cylindrical case having an opening at one end in the axial direction (upper end in the figure), and the opening is closed by a lid 64.
Here, the lid 64 is screwed to the case 62.

The lid 64 is provided with a raw water inlet 66A and a purified water outlet 66B.
The flexible water hose 38A for introducing raw water into the water purifier 40 is connected to the raw water inlet 66A.
The flexible hose 38B that guides outflow of purified water from the water purifier 40 is connected to the purified water outlet 66B.

  On the outer peripheral side of the filling space inside the case 62, an accommodation space 63 for the granular activated carbon layer 65 having a circular donut shape in cross section is formed in the axial direction until reaching the bottom 70, Granular activated carbon 66 is filled. A granular activated carbon layer 65 is formed by the filled granular activated carbon 66.

In this embodiment, granular activated carbon 66 having a particle size of 0.1 to 0.5 mm, an average pore size of 5 to 20 mm, and a specific surface area of 800 to 3000 cm ² / g is used.
Here, the particle diameter means the average particle diameter of the granular activated carbon.
This particle diameter of 0.1 to 0.5 mm is a size generally used in water purifiers. If the particle diameter is smaller than this, the particle diameter is too small and the filling ratio of the granular activated carbon 66 becomes high. Therefore, it is not preferable because the pressure resistance becomes high and water hardly flows.

The specific surface area is the surface area per unit weight of the granular activated carbon particles, and the higher the specific surface area, the higher the adsorption performance.
The average pore diameter is an average pore diameter of pores vacated in the granular activated carbon, and the component to be adsorbed can be selected by changing this size.

The average small-diameter hole of the granular activated carbon generally used in the water purifier is 1 to 7 mm.
On the other hand, in this embodiment, the average pore diameter of the granular activated carbon 66 is 5 to 20 mm, and this makes it possible to favorably adsorb organic substances such as humic acid.
That is, the granular activated carbon 66 of this embodiment adsorbs residual chlorine in tap water, but has a performance capable of selectively adsorbing organic substances such as humic acid in particular.

A cylindrical cylinder 72 is provided on the inner side of the granular activated carbon layer 65 and on the bottom 70 side of the case 62, that is, the lower side in the figure. The cylindrical body 72 is made of a non-permeable material, and a through-permeable hole 74 is formed at a position on the lower side in the drawing, that is, on the bottom 70 side.
An activated carbon fiber layer 76 is accommodated inside the cylindrical body 72.
In the figure, reference numeral 78 denotes a housing space for the activated carbon fiber layer 76, and the activated carbon fiber layer 76 is formed in a state in which an annular gap is formed along the axial direction with the cylindrical body 72 in the housing space 78. Contained.
In addition, non-water-permeable caps 82 and 84 are provided at both ends of the activated carbon fiber layer 76 in the axial direction, and both end surfaces of the activated carbon fiber layer 76 in the axial direction are blocked by the caps 82 and 84. Has been.

This activated carbon fiber layer 76 has a cloth-like form, and is provided in a wound state around a ceramic filter 68 described later as a core.
Innumerable fine pores (pores) are formed on the surfaces of the activated carbon fibers constituting the activated carbon fiber layer 76, and various substances are adsorbed and removed from the tap water in the pores.
The pores of the activated carbon fiber layer 76 are smaller than the pores of the granular activated carbon 66, and components that could not be adsorbed by the granular activated carbon layer 65 can be removed here by adsorption.

  In particular, in this embodiment, the granular activated carbon 66 has a larger pore size than the granular activated carbon normally used in a water purifier, and as a result, the granular activated carbon used in a normal water purifier has the ability to adsorb trihalomethane and residual chlorine in tap water. However, these components are adsorbed well in the activated carbon fiber layer 76 and removed from the tap water.

The activated carbon fiber layer 76 also has a high filtration function with respect to the granular activated carbon layer 65.
Specifically, although the granular activated carbon layer 65 can remove particles that are so large as to be visible by filtration, the filtration function is not so high.
On the other hand, since the activated carbon fiber layer 76 also has the properties of a cloth, small particles that cannot be removed by the granular activated carbon layer 65 can be removed here by filtration.

The ceramic filter 68 has a cylindrical shape made of a porous ceramic sintered body, and diatomaceous earth 80 is integrally laminated on the entire outer peripheral surface thereof.
Here, the diatomaceous earth 80 is baked on the ceramic filter 68.

In the present embodiment, the ceramic filter 68 is made of a porous sintered body of calcium aluminosilicate.
Specifically, it consists of a porous sintered body of calcium aluminosilicate having a composition of SiO ₂ : 75 to 85%, Al ₂ O ₃ : 5 to 10%, and CaO: 10 to 20% by mass%, When it adheres or is immersed in water, it releases antibacterial effects by gradually releasing Ca ²⁺ ions as antibacterial components.

This calcium aluminosilicate is obtained by blending siliceous wax, limestone, and clay such that SiO ₂ , Al ₂ O ₃ , and CaO have the above ratios, and firing and sintering the mixture.
The calcium aluminosilicate having this composition effectively produces a large amount of β-wollastonite (CaO · SiO ₂ ) by firing. This β-wollastonite gradually elutes Ca ²⁺ ions over a long period of time to form a weak alkaline state, thereby acting as an antibacterial.

The calcium aluminosilicate having this composition is known (disclosed in Japanese Patent No. 3612766), and in the present invention, the one disclosed in Japanese Patent No. 3612766 can be suitably used.
Since this calcium aluminosilicate is a known one disclosed in the patent, further detailed explanation is omitted here.

This ceramic filter 68 has a function of removing particulate impurities such as fine iron contained in tap water, organic matters such as humic acid, floc and other solid contents such as aluminum flocculant, that is, turbidity components by filtration. Therefore, it has the ability to filter and remove finer turbid components than the granular activated carbon layer 65 and the activated carbon fiber layer 76.
Here, the ceramic filter 68 has the ability to remove turbid components up to about 0.5 μm in size by filtration.

  A non-permeable cylindrical tubular body 86 is provided on the upper side of the ceramic filter 68 and the activated carbon fiber layer 76 in the drawing and inside the granular activated carbon layer 65, and an accommodation space 88 inside the tubular body 86 is provided. A hollow fiber membrane filter 90 is installed on the surface.

The hollow fiber membrane filter 90 functions to remove finer turbid components that could not be removed by the ceramic filter 68 from the tap water that has passed through the ceramic filter 68 by filtration.
Here, the hollow fiber membrane filter 90 can remove even small turbid components up to 0.1 μm by filtration.
The tap water (purified water) that has passed through the hollow fiber membrane filter 90 and has been purified is discharged to the outside through the purified water outlet 66B.

Note that the upper end of the accommodation space 88 for accommodating the hollow fiber membrane filter 90 in the figure is closed by a cap 92.
The cap 92 is provided with a cylindrical male fitting portion 94, and this male fitting portion 94 is fitted into a female fitting portion 96 provided on the lid 64, thereby causing the hollow fiber membrane filter 90 to The purified water is guided to the purified water outlet 66B.

A mesh filter 98 is disposed below the lid 64 in the drawing.
The mesh filter 98 serves as a presser against the granular activated carbon 66 described above.
The mesh filter 98 also has a function of pressing the cylindrical body 72, the activated carbon fiber layer 76, the ceramic filter 68, the cylindrical body 86 around the hollow fiber membrane filter 90 and the like through the spacer member 100.

In the water purifier 40 of this embodiment, the raw water flowing in from the raw water inlet 66A first flows in the granular activated carbon layer 65 in the axial direction, and then flows into the activated carbon fiber layer 76 side from the water permeable holes 74 of the cylindrical body 72. Then, this is transmitted radially inward.
Further, the ceramic filter 68 in the central portion is permeated from the outer peripheral side to the inner peripheral side, and then the flow is changed upward in the figure, and flows through the hollow fiber membrane filter 90.

  In the course of the flow, the turbid component that becomes a clogging cause substance contained in the tap water is removed from the tap water by filtration action in order from the coarse by the granular activated carbon layer 65, the activated carbon fiber layer 76, the ceramic filter 68, Then, the finest turbid component remaining finally is filtered by the hollow fiber membrane filter 90 and removed from the tap water.

Further, residual chlorine dissolved in tap water, trihalomethane, agricultural chemicals and other harmful components, and odor components such as mold odor are removed by the adsorption action by the granular activated carbon layer 65 and the activated carbon fiber layer 76.
Then, tap water purified by filtration and adsorption, that is, purified water, flows out from the purified water outlet 66B.

In this embodiment, the powder (pulverized calcium aluminosilicate) formed by pulverizing the ceramic filter 68 is housed in the housing space 88 of the hollow fiber membrane filter 90 and the housing space 63 of the granular activated carbon layer 65, respectively. ing.
Specifically, powders having a particle size of 0.15 to 0.30 mm are accommodated in these accommodating spaces 88 and 63 in amounts of 10 g and 30 g, respectively.
The powder is stored in a mixed state with the granular activated carbon 66 in the storage space 63 of the granular activated carbon layer 65.
In the housing space 88 of the hollow fiber membrane filter 90, most of the powder is housed in the adhering state to the wall surface of the hollow fiber membrane filter 90.

The adhesion of the powder to the wall surface of the hollow fiber membrane filter can be performed as follows.
That is, by removing the cap 92 and adding powder in the accommodation space 88, and closing the cap 92 in that state and shaking the whole, the powder particles can be attached to the wall surface of the hollow fiber membrane.

In this embodiment, a predetermined amount of the above powder can be accommodated in the accommodating space 78 of the activated carbon fiber layer 76 and can be adhered to the activated carbon fiber layer 76.
However, instead of this, for example, an antibacterial agent such as silver may be bound and held at the stage of forming the activated carbon fiber.

The tap water flowing in from the raw water inlet 66A is adsorbed by the first granular activated carbon layer 65 to remove chlorine by adsorption, and if no special antibacterial measures have been taken, it is easy for germs to propagate throughout the water purifier 40. Become.
However, in this embodiment, since the antibacterial property is imparted to the entire interior of the water purifier 40, it is possible to favorably prevent the growth of bacteria even under chlorine removal.

<Experimental example 1>
For each of the ceramic powder 10 g contained in the accommodation space 88 of the hollow fiber membrane filter 90 having a capacity of 230 cm ³ and the non-accommodated ceramic powder, water from which residual chlorine has been previously removed is filled to 37 ° C. The number of viable bacteria was measured according to JIS K 3835 according to JIS K 3835 by the plate smear culture method.
The result is shown in FIG.
The powder was put in the storage space 88, and then the storage space 88 was closed with a cap 92. In this state, the whole was shaken by hand to adhere the powder to the wall surface of the hollow fiber membrane.

As shown in FIG. 3, the growth of bacteria was observed over time in the case where powder was not added, but the growth of bacteria was observed in the case where powder was added even after time. I couldn't.
From this, it can be seen that the powder can be put in the antibacterial state satisfactorily by putting the powder in the accommodating space 88 of the hollow fiber membrane filter 90.

<Experimental example 2>
In the water purifier 40 of FIG. 2 having an internal volume of 1100 cm ³ , 10 g of ceramic particle powder (particle size is 0.15 to 0.30 mm) is placed in the accommodating space 88 of the hollow fiber membrane filter 90 having a volume of 230 cm ³ . A clogging durability test of the hollow fiber membrane filter 90 was performed.
For comparison, a similar test was also performed on a sample without powder.

In the test, test water mixed with humic substances and a flocculant was passed through the water purifier 40 by 20 L (liter) per day. Meanwhile, the water purifier 40 was kept in a 37 ° C environment.
The evaluation of clogging durability was performed based on the accumulated water amount until the instantaneous flow rate decreased to 1.25 L / min.
The results are shown in FIG.

As shown in FIG. 4, the hollow fiber filter was clogged with about 600 L when ceramic powder was not put in the accommodation space 88, and the durable life was reached. As a result, the clogging durability was extended to about 900L.
From this result, it can be seen that the clogging of the hollow fiber membrane filter 90 is greatly improved by placing the ceramic powder in the accommodating space 88 of the hollow fiber membrane filter 90 due to its antibacterial properties.

When the number of viable bacteria in the housing space 88 of the hollow fiber membrane filter 90 was measured at the stage where clogging occurred, the viable cell count (CFU) of those not containing ceramic powder was 8.2 ×. Whereas it was 10 ⁵ , the number of viable bacteria was zero for the ceramic powder.
The number of viable bacteria was measured according to JIS K 3835 by a plate smear culture method.

<Experimental example 3>
Test water is prepared by mixing humic substances and flocculants, and the particle size is 0.15 to 0.005 in a test column having different cross-sectional area / length ratios (the volume of the test column is unified to 480 cm ³ ). Filled with 30 mm granular activated carbon.
Then, simulated water was passed through the column, and the chromaticity removal rate by granular activated carbon was examined.
Here, the chromaticity removal rate was measured as follows.
Chromaticity: Measured by a transmitted light measurement method based on JIS S 3200-7.
Removal rate: Calculated by (clean water chromaticity / raw water chromaticity) × 100.

At this time, a hollow fiber membrane module having a membrane area of 0.75 m ² was connected to the downstream side of the test column, and the clogging durability of the hollow fiber membrane module was evaluated.
Here, the durability was measured by maintaining the water pressure when passing an initial flow rate of 2.0 L / min, and determining the accumulated water amount until the instantaneous flow rate was reduced to half of 1.0 L / min as the endurance life.
The results are shown in FIG.

  As shown in FIG. 5, the chromaticity removal with granular activated carbon shows a higher chromaticity removal rate as the ratio of the cross-sectional area / length becomes smaller, that is, as the granular activated carbon layer forming a donut shape becomes longer and narrower. As a result, the removal rate of turbid components increased.

On the other hand, the clogging durability of the hollow fiber membrane module is extended by a decrease in the cross-sectional area / length ratio, but conversely clogging when the cross-sectional area / length ratio becomes smaller than a certain value. As a result, the durability turned to a decreasing trend.
Specifically, the ratio 1.6 at which the maximum clogging durability was obtained peaked, and then the clogging durability decreased as the numerical value decreased.

From these results, in order to balance well the water purification performance of tap water by the granular activated carbon layer and the clogging durability of the hollow fiber membrane filter, the ratio of the cross-sectional area / length is 1.0 to 3.0. It is preferable to be within the range (the clogging durability of the hollow fiber membrane filter is determined by setting the target value of the integrated water amount L as 480L).
In addition, it is guessed that it is based on the following reasons that the clogging durable life of the hollow fiber membrane filter starts to decrease at the ratio of 1.6.

That is, the smaller the cross-sectional area / length ratio, that is, the narrower the filling space of the granular activated carbon, the greater the resistance of the flow caused by the granular activated carbon, and thus the higher the water pressure for securing the initial flow rate of 2.0 L / min. .
The water pressure is also applied to the hollow fiber membrane as it is, and it is assumed that the cause is that the micropores of the hollow fiber membrane are easily clogged by the turbid component being pressed against the hollow fiber membrane by the high water pressure. .

In the present embodiment as described above, the ceramic filter 68 is disposed on the upstream side of the hollow fiber membrane filter 90, and the granular activated carbon layer 65 and the activated carbon fiber layer 76 are further upstream of the ceramic filter 68, and the granular activated carbon layer. By disposing 65 on the upstream side of the activated carbon fiber layer 76, turbid components can be filtered stepwise from large to small and efficiently removed from tap water.
As a result, the amount of turbid components to be removed by the hollow fiber membrane filter 90, the ceramic filter 68, and the activated carbon fiber layer 76 is reduced, the load on them is reduced, and the clogging durability life of the entire water purifier 40 is extended. I'm damned.

  In this embodiment, the antibacterial ceramic powder is accommodated in any of the accommodation space 88 of the hollow fiber membrane filter 90, the accommodation space 63 of the granular activated carbon layer 65, and the accommodation space 78 of the activated carbon fiber layer 76. By doing so, the inside of the water purifier 40 can be brought into an antibacterial state throughout, the inside of the water purifier 40 can be maintained in a sanitary manner, and the deterioration of clogging durability due to the propagation of various bacteria can be reduced. Can be prevented.

Although the embodiment of the present invention has been described in detail above, this is merely an example.
For example, what is shown in FIG. 1 is merely an example of use of the water purifier, and the present invention can be applied even when the water purifier is used in various other forms.
Others In the above embodiment, specific calcium aluminosilicate is used as a ceramic having antibacterial properties, but it is possible to use other than the above examples as ceramics having antibacterial properties. The present invention can be implemented in various modifications without departing from the spirit of the present invention, for example, the internal structure can be configured in a form different from the above example.

DESCRIPTION OF SYMBOLS 40 Water purifier 62 Case 63 Accommodating space 65 Granular activated carbon layer 66A Raw water inlet 66B Purified water outlet 68 Ceramics filter 72 Cylindrical body 74 Water permeation hole 76 Activated carbon fiber layer 78 Accommodating space 88 Accommodating space 90 Hollow fiber membrane filter

Claims (2)

In the water purifier that passes the raw water flowing in from the raw water inlet through the filter medium and purifies it by the filtering action of the filter medium, and allows the purified water to flow out from the purified water outlet,
As the filter medium, comprising a ceramic filter consisting of ceramic sintered body of porous, hollow fiber membrane filter, and grain-like activated carbon layer, and an active carbon fiber layer,
From the upstream side of the flow to the downstream side, the granular activated carbon layer, the active carbon fiber layer, a ceramic filter, I was placed in the order of the hollow fiber membrane filter Thea,
On the outer peripheral side of the bottomed cylindrical casing inside the filling space, in the axial direction of the case provided with the granular activated carbon layer in cross-section a donut ring, the axial direction of the granular activated carbon layer raw water flowing in from the raw water inlet opening A cylindrical body provided on the bottom side in the axial direction of the filling space and on the inner peripheral side of the granular activated carbon layer after flowing into the granular activated carbon layer from the end side and circulating in the granular activated carbon layer in the axial direction through permeable pores, the active carbon fiber layer disposed in a cylindrical shape inside the tubular member, to the active more respective cylindrical the ceramic filter arranged in the center radially inward facing inner carbon fiber layer Passing through the hollow fiber membrane filter disposed on the open end side of the ceramic filter and on the inner side of the granular activated carbon layer, and then flowing out from the water purification outlet. Do Water unit. In Claim 1 , the cross-sectional area of the cross-section of the granular activated carbon layer is ³ to 80 cm ² , the filling volume is 100 to 1000 cm ^3, and the ratio cross-sectional area (cm ²⁾ between the cross-sectional area of the granular activated carbon layer and the axial length. ) / Axial length (cm) is in the range of 1.0 to 3.0.

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