KR100490560B1 - Water purifier for reverse osmotic - Google Patents

Abstract

The present invention is a precipitation filter for filtering particulate matter from raw water; A carbon filter configured to filter chlorine or oxide from the primary water produced by the precipitation filter; A boost pump having a water pressure of the secondary water produced by the carbon filter, but having a pump capacity in a range of 80 psi · 2.0 L / min to 100 psi · 3.5 L / min; A membrane having a volume of 300 GPD to 1000 GPD (gallon / day) in which the final filtered water is produced by filtering the heavy metal or the ionic substance from the secondary purified water boosted by the boost pump; One side of the membrane is a wastewater discharge valve to open and close the wastewater pipe for discharging the wastewater in the membrane; A time sensor for applying an opening / closing signal to the wastewater discharge valve at a predetermined time interval to discharge the wastewater inside the membrane; And a flow sensor on one side of the membrane, the flow sensor applying an open / close signal to the wastewater discharge valve when the wastewater in the membrane is above a certain concentration, wherein the membrane, the wastewater discharge valve, the time sensor, and the flow sensor are electrically connected. It is characterized by consisting of a direct-type structure to remove the reservoir tank.

Description

Reverse osmosis water purifier {Water purifier for reverse osmotic}

The present invention relates to a reverse osmosis water purifier that enables the use of purified water directly in the membrane without a separate reservoir tank.

In general, the reverse osmosis water purifier is a device that accepts tap water or ground water, undergoes water purification work by a reverse osmosis method, and finally provides the purified water to a user.

As shown in FIG. 1, a conventional reverse osmosis water purifier receives a raw water such as tap water and groundwater to remove particulate matter, and a pressure booster to increase the water pressure of raw water flowing from the precipitation filter 1. The purified water passed through the precarbon filter (3) and the free carbon filter (3), which adsorbs and removes chlorine and oxides from the raw water introduced from the pump (2), the boost pump (2), and the heavy metal and ionic Membrane (4) for removing the substance, the filtered water is accommodated in the membrane (4), the post carbon filter (5) for adsorbing and removing gaseous substances dissolved in the filtered water and the filtered water discharged from the post carbon filter (5) , The ultraviolet sterilizer 6 for sterilizing microorganisms and the like in the filtered water, and the storage tank 7 for storing the filtered water sterilized in the ultraviolet sterilizer 6.

Here, the overall operation of the conventional reverse osmosis water purifier is, in FIG. 1, when the raw water switch 9 of the water purifier is turned on, raw water such as tap water or groundwater is introduced into the precipitation filter 1 along the raw water pipe 8. .

In addition, the purified water generated by the precipitation filter 1 is boosted to a constant pressure in the boosting pump 2, the boosted purified water is again put into the pre-carbon filter (3) is subjected to water purification work again.

The purified water discharged from the precarbon filter 3 flows into the membrane 4 to generate primary filtered water.

In addition, the primary filtered water discharged from the membrane 4 passes through the post carbon filter 5 and the ultraviolet sterilizer 6 to generate the final secondary filtered water, and the generated filtered water is stored in the storage tank along the pipe. 7) is stored, and when the drain switch 10 is turned on, the filtered water is supplied to the users through the purified water pipe (11).

On the other hand, when the concentrated water (wastewater) generated during the water purification operation is turned on the removal water switch 12, the concentrated water is discharged to the outside through the wastewater pipe 13 from the membrane (4).

However, the conventional reverse osmosis water purifier has a very small volume of the boost pump and the membrane, and finally, the amount of purified water generated is very small, less than 300 mm / min. In particular, in a public place where a large amount of purified water is required or at a large event, the purified water is supplied to the storage tank. In order to fill, there was an uncomfortable problem of operating the water purifier for a long time.

In addition, in order to increase the flow rate of the storage tank due to the long time operation of the water purifier, the membrane wastewater ratio should be reduced. If the wastewater ratio is reduced, the concentration of the concentrated water in the membrane is increased, thereby greatly reducing the filtration performance of the membrane. The problem is that the life of the membrane is significantly shortened.

For this reason, the large amount of wastewater discharge was indispensable in the structure of the membrane in order to prevent the performance degradation and the shortening of the membrane. In general, the ratio of purified water to wastewater has to be maintained from 1: 3 to 1: 5. .

In addition, the conventional reverse osmosis water purifier has to include components such as a storage tank, an ultraviolet sterilizer, and a post carbon filter, and thus the manufacturing cost is increased. There was a problem threatening the health of the user to breed.

The present invention has been made to solve the above problems, to increase the volume of the boost pump and the membrane to reduce the waste water amount and to maximize the purified water, it is possible to obtain a large amount of purified water without having a separate storage tank It is an object of the present invention to provide a reverse osmosis water purifier capable of generating high purity purified water without installing a post carbon filter and an ultraviolet sterilizer.

According to an aspect of the present invention for achieving the above object, a precipitation filter for filtering particulate matter from raw water; A carbon filter configured to filter chlorine or oxide from the primary water produced by the precipitation filter; A boost pump having a water pressure of the secondary water produced by the carbon filter, but having a pump capacity in a range of 80 psi · 2.0 L / min to 100 psi · 3.5 L / min; A membrane having a volume of 300 GPD to 1000 GPD (gallon / day) in which the final filtered water is produced by filtering the heavy metal or the ionic substance from the secondary purified water boosted by the boost pump; One side of the membrane is a wastewater discharge valve to open and close the wastewater pipe for discharging the wastewater in the membrane; A time sensor for applying an opening / closing signal to the wastewater discharge valve at a predetermined time interval to discharge the wastewater inside the membrane; And a flow sensor on one side of the membrane, the flow sensor applying an open / close signal to the wastewater discharge valve when the wastewater in the membrane is above a certain concentration, wherein the membrane, the wastewater discharge valve, the time sensor, and the flow sensor are electrically connected. It provides a reverse osmosis water purifier, characterized in that made of a direct-type structure to remove the water tank.

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Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the reverse osmosis water purifier according to the present invention.

Figure 2 is a development view showing the configuration of the reverse osmosis water purifier according to the present invention, Figure 3 is a graph showing the water purification performance of the reverse osmosis water purifier according to the present invention.

The overall circuit configuration according to the present invention, as shown in Figure 2, the water supply valve 31 for supplying raw water, such as tap water or groundwater, the raw water pipe (30) is a pipeline for transporting the raw water, the raw water to accommodate the particulate matter A precipitate filter 21 for removing primary water and generating a primary purified water, a carbon filter 22 for generating secondary purified water by adsorbing and removing chlorine and oxides from the primary purified water introduced from the precipitate filter 21, and a secondary purified water. Boosting pump 23 to increase the water pressure of the membrane, the membrane 24 to remove the heavy metals or ionic substances in the second purified water to produce the final filtrate, the concentrated water that is a mixture of the remaining foreign matter generated from the filtered water from the membrane 24 That is, the wastewater discharge valve 25 for controlling the discharge of wastewater, the sensors 26 and 27 for applying an open / close signal to the wastewater discharge valve 25, and the wastewater pipe 29 for discharging the wastewater from the membrane 24. , Carried from the membrane 24 Species is composed of a constant pipe 28 carrying the filtered water.

First, the sedimentation filter 21 firstly introduces raw water such as tap water and groundwater, and generally includes 5 micrometers ( Filter out any debris and contaminants so that the parts of the subsequent process work normally.

In addition, the carbon filter 22 is generally carbon treated at a high temperature, and thus, the membrane 24 is protected by adsorbing and removing chlorine components, rihalmethane (THM), gas chemicals, and the like dissolved in raw water. Allows you to function normally.

The boost pump 23 is preferably provided with a pump capacity in the range of 80 psi 2.0 L / min to 100 psi 3.5 L / min in order to maximize the water pressure of the secondary water purification.

Membrane 24 is to filter out heavy metals, bacteria, organic chemicals or foreign matter having a very low molecular weight, such membrane 24 has a volume in the range of 300GPD to 1000GPD (gallon / day). Preferably, with a volume of about 600 GPD to about 700 GPD, an extraction capacity of about 12.5 L / min can be obtained.

One side of the wastewater pipe 29 connected to the membrane 24 is provided with a time sensor 26 and a flow sensor 27 for applying an open / close signal to the wastewater discharge valve 25, these time sensors 26 and The flow sensor 27 is electrically connected to the membrane 24 and the wastewater discharge valve 25.

The time sensor 26 inputs an opening / closing signal so that the user inputs a predetermined time to the data and opens the wastewater discharge valve 25 according to the predetermined time, and the flow sensor 27 is concentrated water in the membrane 24. The concentration of is periodically checked and an open / close signal is applied to the wastewater discharge valve 25 according to the concentration thereof to open the wastewater discharge valve 25 to periodically discharge the concentrated wastewater from the membrane 24.

On the other hand, the filtered water generated in the membrane 24 is provided directly to the user through the purified water pipe 28 in a direct water form without storing the filtered water by installing a separate reservoir tank. That is, the reverse osmosis water purifier of the present invention has a direct water structure from which the water storage tank is removed.

As shown in FIG. 2, the present invention further includes a control panel 32 through which respective pipes 28, 29, and 30 pass.

The overall operation of the present invention is as follows.

In FIG. 2, after the user turns on the power switch 33 of the control panel 32, the raw water switch 36 of the control panel 32 is turned on.

As the raw water switch 36 is turned on, the raw water is discharged from the water supply valve 31 and introduced into the precipitation filter 21 along the raw water pipe 30. Raw water introduced into the precipitation filter 21 is subjected to filtration, and the filtered purified water is introduced into the carbon filter 22 again.

The carbon filter 22 again filters the introduced purified water, and the purified water discharged from the carbon filter 22 flows into the boosting pump 23. The purified water introduced into the boost pump 23 is increased in water pressure to the membrane 24, and the purified water received in the membrane 24 is again filtered.

At this time, if the user turns on the drain switch 35 of the control panel 32, the filtered purified water is supplied to the user through the purified water pipe (28).

On the other hand, the wastewater concentrated in the membrane 24 is periodically discharged by the wastewater discharge valve 25 by the detection of the time sensor 26 and the flow sensor 27, if the user arbitrarily the membrane 24 In order to discharge the wastewater therein, the wastewater discharge valve 25 of the control panel 32 may be turned on to open the wastewater discharge valve 25 to discharge the wastewater in the membrane 24.

As a result, the membrane, wastewater discharge valve, time sensor and flow sensor are electrically connected.

In an embodiment, the present invention has a larger capacity than that of the conventional membrane, and the boosting pump also has a larger capacity than the conventional boosting pump.

The experiment was conducted to see what effect occurs due to the increased capacity of the membrane, and the experimental conditions and results are shown below.

In the experiment, 400GPD (Gallon / Day) and 150GPD (Gallon / Day) with different membrane capacities were provided, respectively.

With the same experimental conditions for this, the operating condition of the water purifier is 80 psi, the raw water PPM is 80 PPM, and the raw water temperature is 12 It was limited to. In addition, the wastewater discharge rate was 20%, and the relative water recovery rate was limited to 80%.

The water purification operation was performed for 5 minutes, the wastewater control valve was opened for 30 seconds, and the membrane was washed. The water purification efficiency and the load of the membrane filter were examined by repeating the rest time for 9 minutes and 30 seconds.

The results are well shown in the graph of FIG. 3 and in Table 1 below.

     Membrane Capacity 150GPD (Gallon / Day)      Membrane Capacity 400GPD (Gallon / Day)   Time (min)      TDS   TDS removal rate   Time (min)      TDS   TDS removal rate       0      11     84.9       0      12     83.6       One      11     84.9       One      10     86.3       2       7     90.4       2      12     83.6       3       8     89.0       3      12     83.6       4       9     87.7       4      12     83.6       5      11     84.9       5      12     83.6

As shown in the data of Table 1, the total dissolved solids (TDS) for 5 minutes of water purification time when the membrane capacity is 400GPD (Gallon / Day) than when the membrane capacity is 150GPD (Gallon / Day) As the removal rate of) remains constant, we can conclude that the water quality of the purified water is stable.

Figure 3 graphically shows the results of the above data, indicating that the removal rate of total dissolved solids is much more stable for 5 minutes when the membrane capacity is 400GPD (Gallon / Day) than when the membrane capacity is 150GPD (Gallon / Day). You can see at a glance.

Thus, it is concluded that the hydrostatic efficiency and the load of the membrane filter are stabilized as the volume of the membrane is larger.

As another embodiment, the purified water amount was 12 liters (L), the operating time of the water purifier was set to 5 minutes (min), and the waste water quantity was compared when the ratio of the integer: waste water was different.

                      Water purification amount is 12 (L), water purifier operation time is 5 (min)     Integer: wastewater         1: 5         1: 3        4: 1      Wastewater (L)           30           18         4.5

As shown in Table 2 above, the ratio of water: wastewater 1: 5 and 1: 3 is a conventional embodiment adopted in the prior art water purifier, and the ratio of water: waste water 4: 1 is an embodiment to be adopted by the present invention. Yes.

In the data of Table 3 above, when the ratio of water: wastewater is 1: 5 and 1: 3, the wastewater ratio is higher than that of the water ratio, so the amount of wastewater discharged from the membrane is naturally 30 liters and 18 liters, respectively. In contrast, if the ratio of water to wastewater equals 4: 1, the ratio of water to wastewater is higher than that of wastewater, so the amount of wastewater discharged from the membrane is 4.5 liters, so the ratio of water to wastewater is 1: 5 and Compared with 1: 3, the amount of wastewater is lowered.

These results, it can be said that even if only a small amount of wastewater discharged in the membrane instantaneously after a certain period of time in a state in which the wastewater ratio is minimized, there is no abnormality in the water purification efficiency and the life of the membrane.

The present invention can generate a large amount of purified water in a short time without a water tank, and can reduce the wastewater discharge rate without affecting the performance and life of the membrane can be used very efficiently in public places, venues, homes There is this.

In addition, by significantly reducing additional components, such as a water tank and other ultraviolet sterilizers and post carbon filters, compared to conventional water purifiers, it is possible to significantly reduce production costs, thereby providing consumers with low-cost water purifiers. It works.

In addition, by removing the storage tank, there is an effect that can prevent the growth of harmful elements such as microorganisms and mold in the storage tank.

1 is a development view showing the configuration of a conventional reverse osmosis water purifier,

Figure 2 is a development view showing the configuration of the reverse osmosis water purifier according to the present invention,

3 is a graph showing the water purification performance of the reverse osmosis water purifier according to the present invention.

Explanation of symbols on the main parts of the drawing

21; Sedimentation filter 22; Carbon filter

23; Boost pump 24; Membrane

25; Wastewater discharge valve 26; Time sensor

27; Flow sensor 28; Water purification pipe

29; Wastewater pipe 30; Raw water piping

31; Feed valve 32; control panel

33; Power switch 34; Removal water switch

35; Drain switch 36; Raw water switch

Claims (6)

A precipitation filter for filtering particulate matter from raw water; A carbon filter configured to filter chlorine or oxide from the primary water produced by the precipitation filter; A boost pump having a water pressure of the secondary water produced by the carbon filter, but having a pump capacity in a range of 80 psi · 2.0 L / min to 100 psi · 3.5 L / min; A membrane having a volume of 300 GPD to 1000 GPD (gallon / day) in which the final filtered water is produced by filtering the heavy metal or the ionic substance from the secondary purified water boosted by the boost pump; One side of the membrane is a wastewater discharge valve to open and close the wastewater pipe for discharging the wastewater in the membrane; A time sensor for applying an opening / closing signal to the wastewater discharge valve at a predetermined time interval to discharge the wastewater inside the membrane; And One side of the membrane includes a flow sensor for applying an open / close signal to the wastewater discharge valve when the wastewater in the membrane is above a certain concentration, The membrane, the wastewater discharge valve, the time sensor and the flow sensor is electrically connected, reverse osmosis water purifier, characterized in that made of a direct-type structure to remove the reservoir tank. delete delete delete delete delete