JP5072193B2 - Drinker with self-weight filter - Google Patents

Description

  The present invention relates to a self-weight filter device, a self-weight filter, and a drinking water device including these.

Conventionally, an installation type drinker is known, and this drinker is used in homes, offices, conference rooms, rest areas, and the like. A tank or a bottle containing a relatively large volume of drinking water is installed in a drinking device with the opening of the bottle facing down to supply and use water. Usually, it has a structure that allows drinking water in tanks and bottles to pass through and heats and cools, but inside it is a filter for filtration with adsorbents such as activated carbon, stones that add minerals, minerals, etc. Built-in water drinkers are also widely known. Usually, the filter for filtration is filtered by its own weight and allows drinking water to pass therethrough, but there are some that forcibly pass water automatically or manually using a pump or the like.
Moreover, as what obtains the purified water simply, the portable small water purifier which can be easily obtained if a small amount of purified water is known (for example, refer patent document 1).
JP 2002-320967 A

However, in such a conventional drinking device, drinking water that does not contain residual chlorine is put in bottles and tanks, so that bacteria are likely to be generated in the long term, and air is given to the bottles and tanks during use. There is a hygienic problem that bacteria need to be taken in and it is easy for bacteria to enter. Furthermore, when using the pumps described above, maintenance costs are incurred even if a small pump is used, and measures against fine particles, rust, and odors emitted from the pump due to water handling are taken. There is a problem that it leads to cost increase such as necessity.
On the other hand, it is possible to use a portable small water purifier, but in order to use clean water that has passed through the filter of such a water purifier for various things in the home, capacity Is limited. Therefore, there is a demand for a drinking device that is hygienic, large, and capable of reducing costs such as maintenance costs.

 Therefore, the present invention provides a filter for self-weight filtration that can extremely improve the purification accuracy, a self-weight filter device that can purify water by its own weight, and a drinking water device including these.

In order to solve the above problems, the invention according to claim 1 includes an upper collar (for example, upper collar 8 in the embodiment) and a lower collar (for example, lower collar 9 in the embodiment). And a partition wall (for example, the partition wall 10 in the embodiment) is provided between the upper collar portion and the lower collar portion, and an opening portion (for example, the opening portion 11 in the embodiment) is formed in the partition wall. The opening is provided with a filtration filter (for example, the water purification cartridge 12 in the embodiment). The filtration filter includes a cylindrical cap and a main case integrated with the cylindrical cap. A hollow fiber membrane fixed with a resin layer is provided inside the main case, and the lower end of the main case is filtered. A water outlet was formed, and the filtered water filtered through the hollow fiber membrane was collected outside the resin layer, flowed to the filtered water outlet, passed through, and stored in the lower collar.
By configuring in this way, the raw water is stored in the upper heel part, and this raw water is purified by the filtration filter and stored in the lower heel part, so it is purified by its own weight without using a motor or pump. In addition, purified water can be obtained, and furthermore, since raw water is filtered by a filter, it can be used even in land with poor water quality and water conditions.
Moreover, for example, the raw water storage capacity of the upper heel and the purified water storage capacity of the lower heel can be increased.

The invention according to claim 2 is characterized in that a hydrophilic hollow fiber membrane and a hydrophobic hollow fiber membrane fixed by a resin layer are arranged inside the main case in a mixed state.
By comprising in this way, it can prevent that the bubble contained in raw | natural water stagnates on the surface of a hollow fiber membrane, inhibits filtration water flow, and reduces the filtration flow rate. Furthermore, even if the upstream side of the hollow fiber membrane is in a sealed state, air can be taken in through the hydrophobic hollow fiber membrane, so that the self-weight filtration can be continuously performed without stagnation of filtered water. Further, even when the upstream side of the hollow fiber membrane is not sealed, the self-weight filtration can be performed more smoothly than in the case where the hydrophobic hollow fiber membrane is not used.
Further, it is possible to smoothly obtain purified water while sealing the upstream side of the hollow fiber membrane and keeping the raw water more sanitary.
In addition, compared with a portable water purifier, for example, the raw water storage capacity of the upper heel part and the purified water storage capacity of the lower heel part are increased, and the weight is smoothly filtered to ensure sufficient water purification in the lower heel part. be able to.

The invention according to claim 3 is characterized in that the hydrophilic hollow fiber membrane and the hydrophobic hollow fiber membrane have a filling ratio of the hydrophobic hollow fiber membrane of 3 to 50% with respect to the hydrophilic hollow fiber membrane. It is characterized by.
By setting it as such a structure, efficient air intake and self-weight filtration which hold | maintained the appropriate flow volume can be performed simultaneously.

According to the first aspect of the present invention, since the raw water is stored in the upper collar portion, it is possible to obtain purified water by purifying with its own weight without using a motor or a pump.
And since raw water is filtered with a filtration filter, there exists an effect which can be used also in land with bad water quality and water circumstances.
Moreover, for example, the raw water storage capacity of the upper heel and the purified water storage capacity of the lower heel can be increased.

According to the invention described in claim 2, since the bubbles contained in the raw water are stagnated on the surface of the hollow fiber membrane, it is possible to prevent the filtration water flow and prevent the filtration flow rate from decreasing. There is an effect that can be performed smoothly.
Furthermore, even if the upstream side of the hollow fiber membrane is in a sealed state, air can be taken in through the hydrophobic hollow fiber membrane, so that the self-weight filtration can be continuously performed without stagnation of filtered water.
In addition, even when the upstream side of the hollow fiber membrane is not hermetically sealed, the self-weight filtration can be performed more smoothly than when the hydrophobic hollow fiber membrane is not used. There is an effect that can be improved.
Further, it is possible to smoothly obtain purified water while sealing the upstream side of the hollow fiber membrane and keeping the raw water more sanitary.
Moreover, since the raw water storage capacity of the upper heel part and the purified water storage capacity of the lower heel part can be increased, for example, it is possible to use purified water by a large number of people such as stores, offices, conference rooms, rest areas, and homes. There is.

 According to the invention described in claim 3, by making the filling ratio of the hydrophobic hollow fiber membrane 3 to 50% with respect to the hydrophilic hollow fiber membrane, at the same time performing efficient air intake, There exists an effect which can perform the dead weight filtration which maintained the flow volume.

Hereinafter, an example of an embodiment of the present invention will be described with reference to FIGS.
As shown in FIGS. 1 to 4, the drinking water device 1 includes an installation type casing 3 having a square shape with rubber cushions 2 at four corner portions. The casing 3 is provided with an intermediate plate 4 that divides the inside vertically, and the upper portion of the intermediate plate 4 is configured as a purification chamber 5, and the lower portion of the intermediate plate 4 is configured as a device accommodating portion 6.
In the purification chamber 5 at the upper part of the casing 3, an upper collar part 8 having an upper opening 7 and a lower collar part 9 are provided below the upper collar part 8. The upper flange 8 and the lower flange 9 are partitioned by a partition wall 10, and an opening 11 is provided in the partition wall 10. A replacement water purification cartridge 12 to be described later is detachably attached to the opening 11 in a liquid-tight manner.
A lid 13 is attached to the upper opening 7 to prevent entry of dust, dirt, insects, etc. into the upper collar 8.

 As shown in FIG. 5, the water purification cartridge (water purification filter) 12 has a cylindrical cap 15 provided with an intake port 14 for taking in raw water on the upper side, and a filtered water outlet 16 provided at the lower end thereof. The main case 17 is provided. A primary purification section made of an adsorbent such as granular activated carbon 18 is provided on the primary side of the main case 17, and the secondary side is liquid-tightly fixed to the main case 17 with a resin layer 20. A second purification part of the hollow fiber membrane 19 is provided. The hollow fiber membrane 19 is cut off from the filtering material side and the filtered water side by a resin layer 20 made of a potting material such as urethane resin, epoxy resin, or polyolefin resin.

Here, the hollow fiber membrane is as shown below.
The hollow fiber membrane is suitably used for filtration and removal of particles having a size of 0.1 μm or more including microorganisms and bacteria, and various porous and tubular hollow fiber membranes can be used for this hollow fiber membrane. For example, cellulose, polyolefin (polyethylene, polypropylene), polyvinyl alcohol, ethylene / vinyl alcohol copolymer, polyether, polymethyl methacrylate (PMMA), polysulfone, polyacrylonitrile, polytetrafluoroethylene Those composed of various materials such as ethylene fluoride, polyvinylidene fluoride (PVDF), polycarbonate, polyester, polyamide, and aromatic polyamide can be used. Among these, considering the handleability and processing characteristics of the hollow fiber membrane, polyolefin-based hollow fiber membranes such as polyethylene and polypropylene are preferable.

The outer diameter of the hollow fiber membrane is more preferably 20 to 2000 μm, and the pore diameter is more preferably 0.01 to 1 μm, and more preferably 0.01 to 0.4 μm. Here, general bacteria may be allowed to pass through, but in order to surely remove E. coli, it is preferably 0.4 μm or less.
The hollow fiber membrane preferably has a porosity of 20 to 90%, and the hollow fiber membrane has a thickness of 5 to 300 μm. Furthermore, the pore diameter is a value measured by a bubble point measurement method according to ASTM F316-80 or JIS K3832 (partially changed for hollow fiber membrane measurement), and is most preferably 100 kPa or more.

Moreover, the hollow fiber membrane which filters raw | natural water has a hydrophilic group on the surface, and it is desirable that it is what is called a permanent hydrophilization hollow fiber membrane. When the surface of the hollow fiber membrane is hydrophobic, it is very difficult to filter water with the self-pressure of the feed water.
By setting the filling density of the entire hollow fiber membrane to 20 to 70%, more preferably 40 to 65%, and even more preferably 45 to 60%, water flow in the water purification cartridge 12 is achieved. The speed can be increased, and a relatively large amount of raw water can be purified in a short time.
Conversely, the hollow fiber membrane that takes in air is preferably hydrophobic.
In the entire hollow fiber membrane including the hydrophilic hollow fiber membrane and the hydrophobic hollow fiber membrane, the filling ratio of the hydrophobic hollow fiber membrane is preferably 3 to 50% with respect to the hydrophilic hollow fiber membrane. If this filling ratio is too high, the water flow rate decreases, and if it is too low, it is difficult to take air into the bottle, so the water flow rate also decreases. The filling ratio of the hydrophobic hollow fiber membrane is more preferably 5 to 30% with respect to the hydrophilic hollow fiber membrane, although it depends on the form of the channel in the bottle or the drinking water device.

The adsorbent is as shown below.
Examples of the adsorbent include a powder adsorbent, a granular adsorbent obtained by granulating the powder adsorbent, and a fibrous adsorbent. Examples of such adsorbents include natural product-based adsorbents (natural zeolite, silver zeolite, acidic clay, etc.), synthetic adsorbents (synthetic zeolite, bacterial adsorption polymer, hydroxyapatite, molecular sieve, silica gel, silica alumina, etc. Inorganic adsorbents such as gel-based adsorbent, porous glass, titanium silicate, etc., powdered activated carbon, granular activated carbon, fibrous activated carbon, block activated carbon, extruded activated carbon, molded activated carbon, molecular adsorption resin, synthetic granular activated carbon , Ion-exchange resins, ion-exchange fibers, chelate resins, chelate fibers, superabsorbent resins, superabsorbent fibers, oil-absorbent resins, and organic adsorbents such as oil-absorbing materials.

Among them, activated carbon excellent in adsorptive power of organic compounds such as residual chlorine, mold odor, and trihalomethane in raw water, ion exchange resin excellent in adsorption of soluble metal, and synthetic adsorbent are preferably used.
Among activated carbons, granular activated carbon and fibrous activated carbon are preferably used because they have a large contact area with the liquid to be filtered, and have high adsorptivity and water permeability.
Activated carbon includes vegetable matter (wood, cellulose, sawdust, charcoal, coconut shell charcoal, bare ash, etc.), coal (peat, lignite, lignite coal, bituminous coal, anthracite, tar, etc.), petroleum quality (oil residue) , Sulfuric sludge, oil carbon, etc.), pulp waste liquid, synthetic resin, etc., and carbon activated (calcium chloride, magnesium chloride, zinc chloride, phosphoric acid, sulfuric acid, caustic soda, KOH, etc.) as necessary It is done. Examples of the fibrous activated carbon include those obtained by carbonizing and activating a precursor made from polyacrylonitrile (PAN), cellulose, phenol, and coal-based pitch.

As the activated carbon, powdered activated carbon, granular activated carbon obtained by granulating this powdered activated carbon, granular activated carbon, fibrous activated carbon, molded activated carbon obtained by solidifying powder and / or granular activated carbon with a binder, and the like can be used. Among these, granular activated carbon is preferably used from the viewpoint of handleability and cost. As the activated carbon, those having a packing density of 0.1 to 0.7 g / ml, an iodine adsorption amount of 800 to 4000 mg / g, and a particle size of 0.075 to 6.3 mm are preferable.
Furthermore, it is preferable that the adsorbent contains an adsorbent having an antibacterial function because it is more hygienic. Examples of the adsorbent having an antibacterial function include a material obtained by adhering and / or mixing silver to activated carbon.

 Depending on the organic matter to be removed, micropores (pore diameter 20E-10m or less), transitional (pore diameter 20E-10 to 1000E-10m), macropore (pore diameter 1000E-10 to 10000E-10m) It is preferable to use activated carbon adjusted to a pore size that adjusts the ratio of the pore diameters of each activated carbon and maximizes their removal capability. Activated carbon with adjusted pore size may be used alone or may be blended with ordinary activated carbon.

For example, when trihalomethane is to be removed, it is preferable to use activated carbon having a low ratio of macropores and a high ratio of micropores.
Activated carbon may be used alone or in combination with the aforementioned adsorbent. For example, as an adsorbent for removing lead, etc., titanium silicate, hydroxyapatite, zelite, molecular sieve, chelate resin, etc. are filled as a separate layer, mixed and filled, or attached to activated carbon with a binder. Can also be used.
Further, when softening high-grade water, a cation exchange resin is preferably used. Alternatively, an anion exchange resin can be used to remove nitrate nitrogen, nitrite nitrogen, and the like.

 Accordingly, the water that has entered from the intake 14 of the cap 15 of the cartridge described above first flows through the activated carbon 18 and enters the outside of the hollow fiber membrane 19 from the activated carbon 18, and impurities are removed from the surface layer of the hollow fiber membrane. After trapping and filtering, the filtered water enters the inside of the hollow fiber membrane, is collected at the place where the above-described resin layer 20 exits from the inside of the hollow fiber membrane 19, and flows into the filtered water outlet 16. And as shown in FIG. 1, it will flow and will be stored in the lower collar part 9 side.

Here, an outlet port 21 penetrating the intermediate plate 4 is attached to the bottom of the lower collar portion 9. The outlet port 21 is provided with a water purification passage 23 (water pipe) to which a T-shaped connecting pipe (tees) 22 is connected. The water purification passage 23 is branched by the connecting pipe 22, one of which is connected to the first water pipe 24 and the other is connected to the second water pipe 25.
The first water pipe 24 described above is connected to a cold water outlet cock 27 (cold water outlet) as shown in FIG. 1 via a heat exchange portion of a cooling device 26 (cooling heat exchange device). The said cooling device 26 cools purified water with the heat exchanger of a refrigerating cycle.
As shown in FIG. 1, a radiator 28 that dissipates the refrigerant of the cooling device 26 described above is provided on the back surface of the casing 3, and the refrigerant is cooled by air in the radiator 28.

On the other hand, the second water pipe 25 is connected to a hot water (or hot water) outlet cock 30 (hot water outlet) shown in FIGS. This heating device 29 heats the purified water by a heating wire or the like.
Here, as the heating device 29, a device such as a Peltier element that effectively uses the heat released from the radiator 28 of the refrigeration cycle described above may be incorporated to heat the purified water.

As shown in FIGS. 1 and 2, the hot water outlet cock 30 and the cold water outlet cock 27 are attached to the bottom wall of a recess 31 that is recessed toward the back side in the front of the casing 3.
Each of the hot water outlet cock 30 and the cold water outlet cock 27 is provided with respective levers 32 suspended downward from the hot water outlet cock 30 and the cold water outlet cock 27, respectively. Further, water outlets 33, 33 are provided below the hot water outlet cock 30 and the cold water outlet cock 27 so as to face downward. A recovery container 34 is formed in the lower part of the casing 3 corresponding to the water outlets 33, 33. The recovery container 34 recovers the purified water spilled from the hot water outlet cock 30 and the cold water outlet cock 27, and has an upper wall formed in a mesh shape.

 Here, for example, when a container such as a cup (shown by a two-dot chain line in FIG. 1) 33a is pressed against the lower portion of the lever 32, the hot water outlet cock 30 or the cold water outlet cock 27 is opened and purified. When hot water or cold water flows out of the outlets 33 and 33 and is poured into the container, and the container is no longer pressed against the lower portion of the lever 32, the hot water outlet cock 30 and the cold water outlet cock 27 are closed. The hot water or cold water stops flowing out.

 Next, in FIGS. 1 and 3, reference numeral 35 denotes a compressor for the refrigeration cycle. The compressor 35 pressurizes the refrigerant described above, and a control device 36 for controlling the compressor 35 is provided on the front side of the compressor 35. Here, the cooling device 26 and the heating device 29 are fixed on the bottom plate of the casing 3 using a bracket (not shown).

Therefore, according to the first embodiment described above, the installation-type casing 3 is provided, and the upper ridge portion 8 and the lower ridge portion 9 are provided on the upper portion of the casing 3 to sufficiently secure the storage capacity of the purified water. Therefore, it is possible to easily use the purified water at a place used by a large number of people such as a store, an office, a conference room, a resting place, and a home.
In addition, by supplying the purified water to a temperature required by the cooling device 26 and the heating device 29 in the casing 3 of the drinking water device 1 and supplying the purified water to the hot water outlet cock 30 and the cold water outlet cock 27, the water outlets 33, Since the purified hot water and cold water can be obtained from 33, the purified water can be used as hot water or cold water without being contaminated.

Although the drinking water device 1 provided with the cooling device 26 and the heating device 29 has been described in the first embodiment, the cooling device 26 and the heating device 29 may be omitted so that the purified water can be taken out as it is.
Further, a temperature adjustment dial or the like may be provided so that the temperature of the purified water can be arbitrarily set.

FIG. 6 shows a second embodiment of the present invention. This second embodiment is a drinking tank as shown in FIG. 6 above the upper collar 8 of the first embodiment described above. A base 38 for the bottle 37 is provided so that the bottle 37 for water purification (for example, a capacity of about 20 L) can be installed and set in a water drinking device with the opening portion on the lower side.
As shown in FIG. 6, the base 38 has a cylindrical portion 39 formed so as to face the upper collar portion 8 from the opening of the upper wall of the casing 3 of the drinking water device 1, and upward from the upper peripheral edge of the cylindrical portion 39. An abutting member 40 that is formed with an enlarged diameter and that abuts on and receives a shoulder 43 of a bottle 37, which will be described later, and is formed by hanging from the upper edge of the abutting member 40 toward the upper wall of the casing 3. A cylindrical support member 41 is integrally formed.

The bottle 37 includes a bottomed cylindrical body 42, a shoulder 43 having a diameter reduced from the body 42 toward the opening 44, and a mouth 45 that is closed by a cap (not shown) and includes the opening 44. Is formed.
Here, the cap 44 is removed with the opening 44 of the bottle 37 facing downward, and the mouth portion 45 is inserted into the cylindrical portion 39 of the base 38 to set the raw water in the bottle 37 from the mouth portion 45. It will be poured into the buttock 8.
Usually, a bottle dedicated to a drinking water device is sealed with a plastic material or rubber material at the mouth portion 45, and the seal is broken by inserting a protrusion into the central portion of the opening 44 so that the water inside can be taken out. It has a structure. In order to break this seal, no special tool is required, and when the new bottle is installed so that the consumer does not touch it, the seal is automatically broken and there is no water leak. Many structures are known in which a projection is provided at the center of the lower end cylindrical portion 39 of the. It is good also as a structure which took this structure in the casing 3 as it is.
Since other configurations are the same as those of the first embodiment described above, the same parts are denoted by the same reference numerals and description thereof is omitted.

Therefore, according to the second embodiment described above, it is possible to use bottle water that is usually commercially available as it is. In addition, even when bottled water, which has been pointed out as sanitary, is used as raw water, filtered water that has passed through the hollow fiber membrane 19 of the water purification cartridge 12 can be obtained. Purified water can be obtained.
That is, it is not necessary to pump raw water into the upper heel part 8 part by point, and the highly reliable drinking water device 1 can be obtained by setting the bottle 37 itself.

  In addition, this invention is not restricted to the said embodiment, For example, although the said bottle 37 for water purification was set to the upper part of the upper collar part 8, the said bottle 37 itself was utilized as the upper collar part 8, and was mentioned above. The upper collar 8 may be omitted. Further, the hot water outlet cock 30 and the cold water outlet cock 27 may be integrated into a common outlet cock, and the purified water may be taken out by switching between hot water and cold water with a changeover switch.

It is sectional drawing which follows the AA line of FIG. 2 of 1st embodiment of this invention. 1 is a front view of a first embodiment of the present invention. It is a fragmentary sectional view of the back surface of 1st Embodiment of this invention. It is sectional drawing which follows the BB line of FIG. 2 of 1st implementation of this invention. It is a perspective view of the water purification cartridge of 1st embodiment of this invention. It is sectional drawing equivalent to FIG. 1 of 2nd Embodiment of this invention.

Explanation of symbols

8 Upper collar part 9 Lower collar part 10 Partition wall 11 Opening part 19 Hollow fiber membrane 12 Water purification cartridge (purification filter)

Claims (3)

An upper collar part and a lower collar part are provided, a partition wall is provided between the upper collar part and the lower collar part, an opening is formed in the partition wall, and a filtration filter is provided in the opening.
The filtration filter includes a cylindrical cap and a main case integrated with the cylindrical cap. A hollow fiber membrane fixed with a resin layer is provided inside the main case, and filtered water is provided at a lower end of the main case. An exit is formed,
A drinking water device comprising a self-weight filtration device in which filtered water filtered by a hollow fiber membrane is collected outside the resin layer, flows into the filtered water outlet, flows through and is stored in the lower collar portion . . Drinking water device of claim 1 wherein the fixed hollow fiber membrane with a resin layer is characterized by Tei Rukoto arranged in a state where the hydrophilic hollow fiber membrane and a hydrophobic hollow fiber membranes are mixed. 3. The hydrophilic hollow fiber membrane and the hydrophobic hollow fiber membrane are characterized in that a filling ratio of the hydrophobic hollow fiber membrane is 3 to 50% with respect to the hydrophilic hollow fiber membrane. The drinker described.

Images