JP2017042740A - Water purifier - Google Patents

Abstract

PROBLEM TO BE SOLVED: To solve the problem of shortage of treatment water or excessive enlargement of a water purifier, when treating water by a semipermeable membrane module, since the amount of use of water is largely fluctuated at home.SOLUTION: A supply pressure of city water to be supplied to a semipermeable membrane module and/or a flow rate are controlled corresponding to the amount of use of water, to thereby enable stable supply of water to a faucet, and therefore a mechanical load of liquid feed control means (liquid feeding pump) can be reduced, and excessive enlargement of a facility can be prevented.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a water purifier that purifies tap water, groundwater, and the like with a semipermeable membrane.

  Conventionally, water purifiers using separation membranes, especially reverse osmosis membranes, have been provided to remove impurities and microorganisms contained in tap water and groundwater, and to obtain clean water for use in domestic water for beverages, etc. Has been.

  In a conventional water purifier using a reverse osmosis membrane, for example, as shown in Patent Document 1, a technique for separately supplying membrane treated water and mixed water of tap water and concentrated water is shown. In Patent Document 2, the pretreatment of the semipermeable membrane treatment is reduced by using a chlorine-resistant semipermeable membrane. In Patent Document 3, UF membrane treatment is performed after reverse osmosis membrane treatment to supply highly safe purified water with reduced risk of microbial contamination. In Patent Document 4, membrane treated water is stored in a tank, and membrane treatment is performed according to the amount.

Japanese Patent No. 3275409 Japanese Patent No. 3877846 JP-A-2005-205256 Japanese Patent No. 5339702

According to the knowledge of the present inventors, in Patent Document 1, since water other than drinking is not subjected to membrane treatment, and membrane concentrated water is further mixed, water desired as domestic water cannot be obtained. There was a problem. The tap water that uses the groundwater as the raw water tends to have a high hardness, and precipitation of calcareous components and the like becomes a problem, but there is a problem that the technique disclosed in Patent Document 1 cannot solve the problem.
Moreover, in patent document 2, it was difficult to change a processing method smoothly according to the usage-amount of RO permeated water. When increasing the RO permeated water amount, it is necessary to increase the membrane area, and there is a problem that the membrane device is enlarged.
In Patent Document 3, since the amount of water that can be treated by the membrane is limited, the usable applications are limited, and it is necessary to operate the booster pump every time RO permeate is used. Was high.
In Patent Document 4, since membrane treated water is stored in a tank, there is a problem that biofouling occurs in the tank. Moreover, every time RO permeate was used, it was necessary to operate the liquid feed pump, and the mechanical load of the pump was high.

  Some commercially available RO water purifiers are provided with a liquid feed pump to supply tap water to the semipermeable membrane module. In this case, even when a small amount of treated water from the semipermeable membrane module is used from the faucet, it is necessary to operate the liquid feed pump. Living water often uses water intermittently from the faucet, so the frequency of operating / stopping the pump is increased, and the mechanical load increases, which increases the possibility of failure. There was a problem.

  In addition, it is possible to use only the required amount of water from the faucet by continuously operating the liquid feed pump without membrane filtration or circulating the membrane treated water, but complicated operation / stop operation of the liquid feed pump However, it is necessary to operate the liquid feed pump continuously to circulate the membrane treated water. Moreover, since the electric power for operating a liquid feeding pump is also needed, there existed a subject of high operating cost.

In order to solve the above problems, the present invention has the following configurations (1) to (11).
(1) A water purifier that takes in tap water sent from a water source such as a water purification plant or groundwater, and supplies the tap water to one or more water supply ports,
A semipermeable membrane module that separates the tap water into treated water and concentrated water by a semipermeable membrane;
A semipermeable membrane supply line for supplying the tap water to the semipermeable membrane module;
Depending on the treated water supply line for supplying treated water from the semipermeable membrane module to the faucet and the flow rate of treated water and / or the pressure of the treated water supply line, the semipermeable membrane supply line and / or the semipermeable membrane treated water line may be sent. Pressure and / or flow rate control means for controlling the hydraulic pressure and / or flow rate;
Liquid feeding control means installed in the semipermeable membrane supply line;
The water purifier characterized by having.
(2) A water treatment apparatus that takes in tap water sent from a water source such as a water purification plant or groundwater, and supplies the tap water to one or more water supply ports,
A semipermeable membrane module that separates the tap water into treated water and concentrated water by a semipermeable membrane;
A semipermeable membrane supply line for supplying the tap water to the semipermeable membrane module;
Depending on the quality of the treated water supply line and tap water and / or treated water supplied to the faucet of the semipermeable membrane module, the feeding pressure of the semipermeable membrane supply line and / or the semipermeable membrane treated water line and / or Or pressure and / or flow rate control means for controlling the flow rate of liquid flow;
A water purifier having liquid feeding control means installed in a semipermeable membrane supply line.
(3) The semipermeable membrane supply line is at least one supply line, and at least one of the semipermeable membrane supply lines has a liquid feed pump, and the liquid feed control means controls the amount of treated water used. The water purifier according to (1) or (2), wherein the liquid feed pump is operated accordingly.
(4) An activated carbon unit and / or an adsorbent unit that removes a chlorine-based compound and / or a fluorine-based compound in the treated water is provided between the pressure gauge and the faucet (1) to (3) The water purifier in any one of.
(5) The water purifier according to any one of (1) to (4), wherein the semipermeable membrane supply line has a turbidity removing means for removing turbidity in the tap water.
(6) The water purifier according to (5), wherein the turbidity removing means is a UF membrane module and / or an MF membrane module.
(7) The water purifier according to (5) or (6), wherein a liquid feed pump is installed in the tap water supply line to the turbidity removing means.
(8) The UF membrane module and / or MF membrane module of the turbidity removing means is characterized in that the membrane mode is a hollow fiber membrane and the membrane strength is 4.9 N or more, (1) to (7) The water purifier in any one of.
(9) The semipermeable membrane supply line and / or the semipermeable membrane so that the ratio (X / Y) of the treated water amount X of the turbidity removing means to the treated water amount Y of the semipermeable membrane module is 1 or more and 10 or less. The water purifier according to any one of (1) to (8), further comprising pressure and / or flow rate control means for controlling the liquid feed pressure and / or the liquid feed flow rate of the treated water line.
(10) A water purification method that takes in tap water sent from a water source such as a water purification plant or groundwater, and supplies the tap water to one or more water supply ports,
Supplying the tap water to the semipermeable membrane module through the semipermeable membrane supply line;
Separated into treated water and concentrated water by the semipermeable membrane module,
Supply the treated water of the semipermeable membrane module to the faucet through the treated water supply line,
According to the flow rate of the treated water and / or the pressure of the treated water supply line, the liquid feeding pressure and / or the liquid feeding flow rate of the semipermeable membrane supply line and / or the semipermeable membrane treated water line are controlled,
A water purification method characterized by controlling the amount of tap water fed to a semipermeable membrane module through a semipermeable membrane supply line according to the amount of treated water used.
(11) A water purification treatment method that takes in tap water sent from a water source such as a water purification plant or groundwater, and supplies the tap water to one or more water supply ports,
Supplying the tap water to the semipermeable membrane module through the semipermeable membrane supply line;
Separated into treated water and concentrated water by the semipermeable membrane module,
Supply the treated water of the semipermeable membrane module to the faucet through the treated water supply line,
According to the quality of the tap water and / or treated water, the liquid feeding pressure and / or the liquid feeding flow rate of the semipermeable membrane supply line and / or the semipermeable membrane treated water line are controlled,
An operation method of a water purifier, wherein the amount of tap water fed to a semipermeable membrane module through a semipermeable membrane supply line is controlled according to the amount of treated water used.

  According to the water purifier according to the present invention, safe and high-quality water can be stably supplied, the mechanical load of the liquid feed pump can be reduced, and the RO membrane area can be suppressed.

FIG. 1 shows a flow diagram of a tap water purifier using the semipermeable membrane module of the present invention. FIG. 2 shows a flow diagram of a tap water purifier using a semipermeable membrane module equipped with the turbidity removal apparatus and adsorption unit of the present invention.

  Hereinafter, the present invention will be described in more detail.

FIG. 1 is a schematic view showing an example of a fresh water generator for carrying out the fresh water generation method of the present invention.
(1) Semipermeable membrane module The processing method shown in FIG. 1 includes a semipermeable membrane module supply line 2 through which tap water flows into the semipermeable membrane module 1. Here, the semipermeable membrane is a semipermeable membrane that allows some components in the solution, for example, a solvent to pass therethrough and does not allow other components to pass therethrough. Examples of semipermeable membranes include nanofiltration (NF) membranes and reverse osmosis (RO) membranes.

  The NF membrane and the RO membrane have a performance capable of reducing the solute contained in the water to be treated to a concentration that can be used as reclaimed water. Specifically, NF membrane and RO membrane are various ions such as salt and mineral components, for example, divalent ions such as calcium ion, magnesium ion and sulfate ion, sodium ion, potassium ion and chlorine ion. It has the ability to separate monovalent ions and soluble organic substances such as humic acid (molecular weight Mw ≧ 100,000), fulvic acid (molecular weight Mw = 100 to 1,000), alcohol, ether, saccharide and the like.

  The semipermeable membrane desirably has chlorine resistance. Thereby, it is not necessary to remove chlorine before the semipermeable membrane treatment, and water containing chlorine flows to the treated water supply line, so that biofouling can be suppressed. If chlorine is removed in front of the semipermeable membrane, contamination such as biofouling may occur inside the semipermeable membrane and in the treated water supply line, but cleaning of the supply line, as well as disinfectants and oxidizing agents, etc. It is possible to reduce or suppress the contamination of the supply line by adding a medicine or the like.

The NF membrane is not particularly limited, but may be defined as a filtration membrane having an operation pressure of 1.5 MPa or less, a fractional molecular weight of 200 to 1,000, and a sodium chloride rejection of 90% or less. The RO membrane has a smaller molecular weight cut off and higher blocking performance. Also, the RO film close to the NF film is also called a loose RO film.
The shape and mode of the membrane used are not particularly limited, and flat membranes, hollow fiber membranes, tubular membranes, and any other shapes can be used as appropriate.
(2) Supply of treated water of semipermeable membrane module Water treated by the semipermeable membrane is supplied to the faucet 15 from the treated water supply line 4. When the amount of treated water used by the semipermeable membrane module 1 at the faucet 15 is small, the first liquid supply line valve 11 is opened and tap water is supplied to the semipermeable membrane module 1 only by the first liquid supply line 9. To do.
At this time, the second liquid feed line valve 12 is closed, the liquid feed control means (liquid feed pump) 13 is stopped, and tap water is not supplied from the second liquid feed line 10 to the semipermeable membrane module 1. Good. From the viewpoint of mechanical protection of the liquid feeding control means (liquid feeding pump) 13, an electromagnetic valve or the like may be provided in the line of the liquid feeding control means (liquid feeding pump) 13 so that water does not pass therethrough. Details of the liquid feeding control means (liquid feeding pump) 13 will be described later.
Here, when the liquid feeding control means (liquid feeding pump) 13 is stopped, the second liquid feeding line valve 12 is opened, and tap water is supplied through the gap of the liquid feeding control means (liquid feeding pump) 13. Also good.

  On the other hand, when the amount of treated water used by the semipermeable membrane module 1 at the faucet 15 is large, the first liquid supply line valve 11 is closed and tap water is not supplied from the first liquid supply line 9 to the semipermeable membrane module 1. Not supplied. The second liquid supply line valve 12 is opened, the liquid supply control means (liquid supply pump) 13 is operated, the supply pressure to the semipermeable membrane module 1 is increased, and tap water is supplied.

  By setting it as such a structure, the membrane area of the semipermeable membrane module 1 can be restrained rather than the case where it does not have the liquid feeding control means (liquid feeding pump) 13, but is only the 1st liquid feeding line 9. FIG. Furthermore, the frequency of operation / stop of the liquid feeding pump 13 can be suppressed as compared with the case of only the second liquid feeding line 10 having the liquid feeding control means (liquid feeding pump) 13. (Liquid pump) 13 has the merit of reducing the mechanical load.

In addition, the liquid feeding line to the semipermeable membrane module 1 is one, that is, only the second liquid feeding line may be used. In the form of only the second liquid feeding line, when the amount of treated water of the semipermeable membrane module 1 at the faucet 15 is small, the liquid feeding control means (liquid feeding pump) 13 is stopped and the second liquid feeding line is stopped. Water is supplied to the semipermeable membrane module 1 through a line. With this configuration, when the amount of treated water used by the semipermeable membrane module 1 at the faucet 15 is large, the same effect as described above can be obtained by operating the liquid feed control means (liquid feed pump) 13. . In the case of the form of only this second liquid feed line, water is supplied while the liquid feed control means is stopped, so when using a liquid feed pump for the liquid feed control means, for example, it is difficult to send liquid with a gear pump, In addition, since other pump types may impose a mechanical load on the pump, it is necessary to select the pump type.
Further, as described above, when the amount of the semipermeable membrane treated water at the faucet 15 is large, the liquid feeding control described above is performed in order to increase the liquid feeding pressure to the semipermeable membrane module 1 and increase the throughput of the semipermeable membrane module 1. In addition to operating the means (liquid feeding pump) 13, for example, water from a tank installed at a high place in the second liquid feeding line may be supplied. Further, the water in the tank may be pushed out with high pressure using pressurized air. These liquid feeding control means will be described later.
(3) Pressure and Flow Control Unit Here, whether the amount of water supplied to the semipermeable membrane module 1 is sufficient or insufficient can be determined by, for example, a pressure gauge or / and a flow meter. In FIG. 1, a pressure gauge 5 and a flow meter 6 are installed in the treated water supply line 4. These pressure gauges and / or flow meters are used to control the pressure and / or flow rate control means so that the set pressure and / or flow rate is obtained.

For controlling the pressure and / or flow rate, for example, when using a liquid feed control means (liquid feed pump) 13 for feeding water, by increasing or decreasing the output of the liquid feed control means (liquid feed pump) 13, The pressure and / or flow rate can be controlled. Alternatively, the pressure and / or flow rate can be controlled by providing a control valve on the secondary side of the liquid supply control means (liquid supply pump) 13 for supplying water and increasing or decreasing the opening of the control valve. .
When the amount of treated water of the semipermeable membrane module 1 from the faucet 15 is not used, the pressure gauge 5 indicates the pressure applied to the permeation side of the semipermeable membrane module, and the flow meter 6 indicates the treated water supply line 4 or the like. If there is no water leakage, the flow rate is zero.
Here, when the amount of treated water used in the semipermeable membrane module 1 from the faucet 15 increases, the pressure applied to the permeate side of the semipermeable membrane module 1 is released from the faucet 15 to supply water. Decreases, and the indicated value of the pressure gauge 5 decreases. Moreover, since a flow occurs in the treated water supply line 4, the indicated value of the flow meter 6 increases.

In FIG. 1, when the indicated value of the pressure gauge 5 and / or the flow meter 6 is equal to or smaller than a set value,
Tap water is supplied from the first liquid supply line 9. When the amount of treated water of the semipermeable membrane module 1 at the faucet 15 further exceeds a certain set value and the indicated value of the pressure gauge 5 and / or the flow meter 6 further increases, supply the tap water to the first supply. By switching from the liquid line 9 to the second liquid supply line 10, tap water is supplied using a liquid supply control means (liquid supply pump) 13. By increasing the tap water supply pressure to the semipermeable membrane module 1 using the liquid feeding control means (liquid feeding pump) 13, the amount of supplied water can be increased even with the membrane area of the same semipermeable membrane module 1.

The set value of the pressure gauge 5 and / or the flow meter 6 is set so that the treated water amount of the semipermeable membrane module 1 from the faucet 15 can ensure the set amount or more.
The pressure gauge 5 and / or the flow meter 6 can also be installed in the semipermeable membrane module supply line. When the amount of treated water in the semipermeable membrane module 1 exceeds the set value, the liquid feed control means (liquid feed pump) 13 is operated to increase the supply pressure to the semipermeable membrane module 1, and the semipermeable membrane module 1 is treated. The amount of water can be increased.

  In addition, the pressure gauge 5 and / or the flow meter 6 can be installed on the primary side (filtered side) of the turbidity removal device 17. When the amount of treated water in the semipermeable membrane module 1 exceeds the set value, the liquid feed control means (liquid feed pump) 13 is operated to increase the supply pressure to the semipermeable membrane module 1, and the semipermeable membrane module 1 is treated. The amount of water can be increased. The turbidity removal device 17 will be described later.

The second liquid feeding line can also be installed on the primary side (filtered side) of the turbidity removal device 17. When the amount of treated water in the semipermeable membrane module 1 exceeds the set value, the liquid feeding control means (liquid feeding pump) 13 is operated to increase the supply pressure to the turbidity removing device 17 and the semipermeable membrane module 1 to make the semipermeable membrane The amount of treated water in the membrane module 1 can be increased.
Moreover, when supplying tap water to the turbidity removal device 17 and / or the semipermeable membrane module 1, the tap water supplied to the turbidity removal device 17 and / or the semipermeable membrane module 1 and / or the treatment of the turbidity removal device 17 is performed. Depending on the quality of the water, it may be determined whether to operate the liquid feeding control means (liquid feeding pump) 13.
If the quality of water supplied to the turbidity removal device 17 and / or the semipermeable membrane module 1 is poor, the amount of treated water in the semipermeable membrane module 1 may be reduced, but the liquid feed control means (liquid feed pump) 13 is operated. Thus, the throughput of the turbidity removal device 17 and / or the semipermeable membrane module 1 can be ensured.
For the water quality, general water quality measurement indicators and devices can be used. For example, the total amount of metal ions and the like in tap water can be determined by measuring conductivity. A turbidity meter can determine the turbid mass in tap water.
(4) Liquid supply control means The supply of water to the semipermeable membrane module 1 can be performed by the liquid supply control means (liquid supply pump) 13. As for the control of liquid feeding, for example, when using a liquid feeding control means (liquid feeding pump) 13 for feeding water, the liquid feeding is controlled by increasing or decreasing the output of the liquid feeding control means (liquid feeding pump) 13. Can be controlled. Alternatively, the liquid supply can be controlled by providing a control valve on the secondary side of the liquid supply control means (liquid supply pump) 13 for supplying water and increasing or decreasing the opening of the control valve.
A liquid feed pump can be used as the liquid feed control means. The form of the liquid feed pump is not particularly limited, and a centrifugal pump, a gear pump, a diaphragm pump, or the like can be used. It is necessary to be able to maintain the liquid feeding pressure so that the semipermeable membrane module can be filtered.
As for the liquid feeding control means, in addition to the liquid feeding pump, for example, water from a tank installed at a high place in the second liquid feeding line may be supplied. Further, the water in the tank may be pushed out with high pressure using pressurized air.

In the apparatus for supplying water using the semipermeable membrane module as in the present application, the membrane area of the semipermeable membrane module is set so that the amount of the semipermeable membrane module treated water from the faucet 15 can correspond to the assumed maximum amount. It is necessary to secure.
For example, in Japan, the water pressure is determined by the Water Supply Law, and the pressure of the water main pipe is determined to be 0.15 MPa or more and 0.75 MPa or less. The normal tap water supply pressure is about 0.2 to 0.4 MPa, but even if tap water is supplied to the semipermeable membrane module 1 at this pressure, the amount of treated water in the semipermeable membrane module is limited. Become.
For example, when a semipermeable membrane module with a membrane area of 7 m ² is filtered with a water pressure (0.15 MPa) and treated with a treatment water amount of 0.2 m ³ / m ² / d per unit membrane area, about 1 L / min Treated water can be obtained. For example, when a small amount of water is used from the tap 15, the above-described amount of water may be sufficient.
On the other hand, when supplying tap water to the semipermeable membrane module 1 at a pressure exceeding the tap pressure using a feed control means (feed pump) 13 such as storing water in a bath or using water in cooking. The amount of treated water in the semipermeable membrane module 1 can be increased even with the same membrane area of the semipermeable membrane module 1, the required membrane area of the semipermeable membrane module 1 can be reduced, and the apparatus can be reduced in size and equipment cost. Can be reduced.

  For example, when the water pressure of the treated water supply line is measured by the pressure gauge 5 and / or the flow meter 6 and the pressure and / or flow rate is reduced to a predetermined pressure and / or flow rate when the pressure falls below a certain pressure and / or flow rate, Alternatively, control is performed by the flow rate control means 14. By this control, the liquid feeding control means (liquid feeding pump) 13 is operated, the second liquid feeding line valve is opened, the supply pressure to the semipermeable membrane module is increased, and the amount of permeated water is increased. Can be supplemented.

  In the case of the above cases, in a system that assumes an apartment house, if a large amount of water is temporarily used in each household, such as washing, water supply to the bath, shower, etc., the amount of water may be insufficient. By using this technique, the film area can be suppressed.

  In addition, the concentrated water generated by the semipermeable membrane treatment can be used as flush water for toilets, cleaning water, or emergency water.

  In the present application, when the treated water supply of the semipermeable membrane module 1 is less than the amount of water that can be membrane-filtered with tap water pressure, it is not necessary to operate the liquid supply control means (liquid supply pump) 13. The mechanical load and operation cost of the pump 13 can be reduced.

Here, the ratio (X / Y) of the treated water amount X of the turbidizer 17 and the treated water amount Y of the semipermeable membrane module 1 is not particularly limited with respect to the treated water amount of the turbidizer 17 and the semipermeable membrane module 1. Is preferably 1 or more and 10 or less. More preferably, it is 1.01 or more and 4 or less.
The treated water amount X of the turbidizer 17 and the treated water amount Y of the semipermeable membrane module 1 can be obtained from the amount of water in the filtration step, except for the value when the operation is stopped by membrane cleaning or the like.
As described above, the water purification apparatus of the present application takes in tap water sent from a water source such as a water purification plant or groundwater, and supplies the tap water to one or a plurality of water supply ports. Supply to the semipermeable membrane module through the line, separate into treated water and concentrated water by the semipermeable membrane module, supply the treated water of the semipermeable membrane module to the faucet through the treated water supply line, and The semi-permeable membrane supply line and / or the semi-permeable membrane treated water line are controlled in accordance with the pressure of the treated water supply line, and the semi-permeable membrane is controlled according to the amount of water used. Controls the amount of tap water delivered to the semipermeable membrane module through the supply line.
Alternatively, the tap water is supplied to the semipermeable membrane module through the semipermeable membrane supply line, separated into treated water and concentrated water by the semipermeable membrane module, and the treated water of the semipermeable membrane module is supplied to the faucet through the treated water supply line. Depending on the quality of the supplied tap water and / or treated water, the liquid supply pressure and / or flow rate of the semipermeable membrane supply line and / or the semipermeable membrane treated water line are controlled to control the amount of treated water used. In response, the amount of tap water fed to the semipermeable membrane module through the semipermeable membrane supply line is controlled.
(5) Adsorption device FIG. 2 includes an adsorption device 18 on the primary side of the faucet. Thereby, the odor contained in the treated water of the semipermeable membrane module 1, residual chlorine, a chlorine compound, a fluorine compound, an organic substance, etc. can be removed. The adsorbing device 18 is not particularly limited as long as it is suitable for adsorbing odors, residual chlorine, chlorine-based compounds, fluorine-based compounds, organic substances, and the like. For example, activated carbon, calcium sulfite, zeolite, and other polymer-based adsorbents. Etc. can be used. Moreover, it is also possible to use these adsorbents in combination. For example, when activated carbon is used as one of the adsorbents, it is preferable in that it can maintain the performance of removing residual chlorine even after long-term use and can adsorb organic substances and odors and can be obtained at low cost. Examples of activated carbon materials include coconut shells, phenolic resins, and charcoal.

Here, when chlorine is removed, biofouling occurs. Therefore, it is desirable to install the adsorption device 18 immediately before the faucet.
(6) Turbidity Removal Device FIG. 2 has a turbidity removal device 17 in front of the semipermeable membrane module 1. Thereby, the turbidity contained in tap water is removed, and it becomes possible to operate the semipermeable membrane module 1 stably for a long period of time.

The turbidity removal device 17 is not particularly limited as long as it has a function of removing turbidity, but sand filtration, filters, MF membranes, UF membranes, etc. are exemplified, and one of these is selected, or two or more are selected. A combination or the like is preferably used.
In particular, a UF membrane and an MF membrane are preferable because they are excellent in turbidity removal performance, ease of maintenance and stability. The membrane to be used is not particularly limited, and a flat membrane, a hollow fiber membrane, a tubular membrane, or any other shape can be appropriately used. The material of the membrane is not particularly limited, but at least selected from the group consisting of polyacrylonitrile, polyphenylene sulfone, polyphenylene sulfide sulfone, polyvinylidene fluoride, polypropylene, polyethylene, polysulfone, polyvinyl alcohol, cellulose acetate, ceramics, and other inorganic materials It is preferable that 1 type is included.

  In particular, the hollow fiber membrane can be preferably used because of the merit that the membrane area per unit device area can be increased. For hollow fiber membrane modules, filtration methods such as total filtration and cross-flow filtration can be adopted, but in order to effectively remove turbidity accumulated in the hollow fiber membrane module, flushing with water or the permeate side of the membrane Therefore, reverse pressure cleaning and air cleaning in which the liquid is passed from the raw material side to the stock solution side can be employed. At this time, if the fluid linear velocity is increased, the cleaning effect can be improved. Therefore, it is preferable that the film has high strength. The membrane strength of the hollow fiber membrane is preferably 4.9 N or more, more preferably 9.8 N or more.

DESCRIPTION OF SYMBOLS 1 Semipermeable membrane module 2 Semipermeable membrane supply line 3 Concentrated water supply line 4 Treated water supply line 5 Pressure gauge 6 Flowmeter 7 1st branch part 8 2nd branch part 9 1st liquid feed line 10 2nd liquid feed line 11 First liquid feed line valve 12 Second liquid feed line valve 13 Liquid feed control means (liquid feed pump)
14 Pressure / flow rate control means 15 Faucet 16 Check valve 17 Turbidity removal device 18 Adsorption device

Claims (11)

A water purifier that takes in tap water sent from a water source such as a water purification plant or groundwater, and supplies the tap water to one or more water supply ports,
A semipermeable membrane module that separates the tap water into treated water and concentrated water by a semipermeable membrane;
A semipermeable membrane supply line for supplying the tap water to the semipermeable membrane module;
Depending on the treated water supply line for supplying treated water from the semipermeable membrane module to the faucet and the flow rate of treated water and / or the pressure of the treated water supply line, the semipermeable membrane supply line and / or the semipermeable membrane treated water line may be sent. Pressure and / or flow rate control means for controlling the hydraulic pressure and / or flow rate;
Liquid feeding control means installed in the semipermeable membrane supply line;
The water purifier characterized by having. A water purification apparatus that takes in tap water sent from a water source such as a water purification plant or groundwater, and supplies the tap water to one or more water supply ports,
A semipermeable membrane module that separates the tap water into treated water and concentrated water by a semipermeable membrane;
A semipermeable membrane supply line for supplying the tap water to the semipermeable membrane module;
Depending on the quality of the treated water supply line and tap water and / or treated water supplied to the faucet of the semipermeable membrane module, the feeding pressure of the semipermeable membrane supply line and / or the semipermeable membrane treated water line and / or Or pressure and / or flow rate control means for controlling the flow rate of liquid flow;
A water purifier having liquid feeding control means installed in a semipermeable membrane supply line. The semipermeable membrane supply line is at least one supply line, and has a liquid feed pump in at least one of the semipermeable membrane supply lines. The water purifier according to claim 1 or 2, wherein the water pump is operated. The activated carbon unit and / or the adsorbent unit for removing the chlorine-based compound and / or the fluorine-based compound in the treated water is provided between the pressure gauge and the faucet. Water purification equipment. The water purification apparatus according to any one of claims 1 to 4, further comprising a turbidity removing means for removing turbidity in the tap water in the semipermeable membrane supply line. 6. The water purifier according to claim 5, wherein the turbidity removing means is a UF membrane module and / or an MF membrane module. The water purifier according to claim 5 or 6, wherein a liquid feed pump is installed in the tap water supply line to the turbidity removing means. The UF membrane module and / or MF membrane module of the turbidity removing unit is characterized in that the membrane mode is a hollow fiber membrane and the membrane strength is 4.9 N or more. Water purification equipment. The semipermeable membrane supply line and / or the semipermeable membrane treated water line so that the ratio (X / Y) of the treated water amount X of the turbidity removing means and the treated water amount Y of the semipermeable membrane module is 1 or more and 10 or less. The water purifier according to any one of claims 1 to 8, further comprising a pressure and / or flow rate control means for controlling the liquid feed pressure and / or the liquid feed flow rate. A water purification method that takes in tap water sent from a water source such as a water purification plant or groundwater, and supplies the tap water to one or more water supply ports,
Supplying the tap water to the semipermeable membrane module through the semipermeable membrane supply line;
Separated into treated water and concentrated water by the semipermeable membrane module,
Supply the treated water of the semipermeable membrane module to the faucet through the treated water supply line,
According to the flow rate of the treated water and / or the pressure of the treated water supply line, the liquid feeding pressure and / or the liquid feeding flow rate of the semipermeable membrane supply line and / or the semipermeable membrane treated water line are controlled,
A water purification method characterized by controlling the amount of tap water fed to a semipermeable membrane module through a semipermeable membrane supply line according to the amount of treated water used. A water purification method that takes in tap water sent from a water source such as a water purification plant or groundwater, and supplies the tap water to one or more water supply ports,
Supplying the tap water to the semipermeable membrane module through the semipermeable membrane supply line;
Separated into treated water and concentrated water by the semipermeable membrane module,
Supply the treated water of the semipermeable membrane module to the faucet through the treated water supply line,
According to the quality of the tap water and / or treated water, the liquid feeding pressure and / or the liquid feeding flow rate of the semipermeable membrane supply line and / or the semipermeable membrane treated water line are controlled,
An operation method of a water purifier, wherein the amount of tap water fed to a semipermeable membrane module through a semipermeable membrane supply line is controlled according to the amount of treated water used.

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