KR102307286B1 - Apparatus for treating concentrated water of reverse osmosis equipment - Google Patents

Abstract

The present invention relates to a concentrated water treatment apparatus of a reverse osmosis facility for water treatment by reverse osmosis. The concentrated water treatment apparatus includes an inlet unit to which raw water is supplied; a pumping unit for pumping and inputting raw water; a reverse osmosis filtration unit for filtering raw water by reverse osmosis; a treated water outlet unit for discharging treated water; a concentrated water discharge unit for discharging concentrated water; and a recovery unit for selectively recovering the concentrated water discharged from the concentrated water discharge unit and supplying the same to the reverse osmosis filtration unit. Therefore, according to the present invention, concentrated effluent generated at the same time during the production of treated water is not used in a separate reprocessing process or mixed and diluted in feed water at a certain ratio, so that it is possible to produce treated water without discharging concentrated water during operation. In addition, when the set time or water quality is reached, only the water in the filter container is automatically discharged, thereby enabling economical, high-efficiency, high-recovery operation without degradation of the filter or reverse osmosis membrane.

Description

Concentrated water treatment device of reverse osmosis equipment {APPARATUS FOR TREATING CONCENTRATED WATER OF REVERSE OSMOSIS EQUIPMENT}

The present invention relates to a concentrated water treatment apparatus for a reverse osmosis facility, and more particularly, to a concentrated water treatment apparatus for a reverse osmosis facility for filtering raw water by reverse osmosis.

In general, in the field of water treatment that purifies sewage/wastewater or sewage/wastewater (hereinafter referred to as “wastewater” for convenience), production water is obtained by filtering pollutants in wastewater using a membrane.

Separation membrane is suitable not only for general filtration that separates undissolved particles by selectively passing specific components, but also for separating and removing suspended substances such as colloids and fine particles in wastewater. It refers to a membrane made of a special material that can even separate gases.

These separation membranes are, depending on their performance, a microfiltration membrane (MF), an ultra filtration membrane (UF), a nano filtration membrane (NF; Nan filtration membrane), a reverse osmosis membrane (RO; Reverse Osmosis Membrane), an ion exchange membrane (IE; It is divided into Ion Exchange), Electrolyte Dialysis (ED), Gas Separation/PV (GAS), and Hem Dialysis, and is appropriately selected according to the purpose of use.

In addition, depending on the shape of the separator, spiral-wound, hollow-fiber, tubular type, plate & frame type, hollow-fiber type, and monolithic module (Monolith type), etc.

Although there are various operating methods for the water treatment process using the separation membrane as described above, it is difficult to minimize the contamination and load of the membrane in treating high-concentration wastewater or concentrating the contaminants or materials to be recovered, the efficiency is low due to the low recovery rate, and the concentration There is a problem with reprocessing the number.

In addition, the low recovery rate in the water treatment process using the separation membrane is a characteristic of supplying raw water at a large flow rate compared to the production water, so a relatively large power is required, which may increase the water treatment operating cost.

Recently, the importance of reusing treated wastewater discharged from wastewater treatment plants is increasing. Accordingly, reuse of treated wastewater is obligatory, and standards for recommending water quality for reused water are being prepared.

The reused water production method can be constructed based on various water treatment processes that can appropriately remove contaminants contained in wastewater treated water to suit the intended use.

However, treatment of concentrated water generated in the water treatment process is emerging as a new problem. Concentrated water is water that cannot be included in reused water, and is water in which contaminants such as solutes and suspended materials are concentrated.

In the case of such concentrated water, depending on the water quality, it must be reprocessed and discharged to meet the discharge water quality standards or discarded through expensive waste treatment procedures. It is known that the amount of concentrated water generated is close to about 20-30% of the amount of inflow treated water. Therefore, there is a problem that the cost of treatment and disposal of concentrated water can become an economic burden in the field of wastewater treatment and reuse, thereby seriously lowering the economic efficiency of the reused water production method.

As described above, in the reverse osmosis apparatus, feed water, concentrated water, and treated water are divided at a certain ratio. For this reason, since reverse osmosis equipment is used for the purpose of purification or separation of inorganic ions, a certain amount of concentrated effluent must have to throw it away

In addition, in the case of two- and three-array configurations, fouling contamination by fine particles occurs in the front-end filter or reverse osmosis membrane, and scale contamination due to ion concentration occurs in the rear-end filter or reverse osmosis membrane.

As a result, contamination of the filters generated in the filter container occurs unequally, making efficient management and maintenance difficult. As a certain amount of concentrated water is always discharged during operation, there is a problem in that there is a significant economic burden such as a quantitative loss of feed water and an increase in power cost, as well as the need to introduce an additional concentrated and discharged water reprocessing process or treatment problems due to an increase in the amount of concentrated water discharged.

Republic of Korea Patent No. 10-1481079 (January 12, 2015) Republic of Korea Patent No. 10-1421386 (July 18, 2014) Republic of Korea Patent No. 10-1898225 (October 29, 2018)

The present invention has been devised to solve the problems of the prior art, and does not mix and dilute concentrated effluent that occurs simultaneously in a separate reprocessing process or feed water at a certain ratio in a separate reprocessing process or feed water, and discharge concentrated effluent during operation. Concentrated water of reverse osmosis facility that can produce treated water without the need for treatment and can automatically discharge only the water in the filter container when the set time or water quality is reached, enabling economical, high-efficiency, high-recovery operation without deterioration of filter or reverse osmosis membrane performance The purpose is to provide a processing device.

In addition, the present invention improves the flow rate in the filter container by recovering the entire amount without discharging concentrated water during operation to suppress scale adhesion on the filter surface due to concentration polarization, and by discharging only water into the filter container when the saturation concentration is higher than the saturation concentration, feed water Another purpose is to provide a concentrated water treatment device of a reverse osmosis facility that can improve the durability of a filter or reverse osmosis membrane by reducing the quantitative loss of do.

In addition, the present invention is drawn out to solve problems such as the increase in operating cost, such as shortening the lifespan of the filter, by minimizing the contamination caused by the imbalance of the filter or reverse osmosis membrane accompanying the quantitative loss of the feed water due to the concentrated effluent compared to the production water and the arrangement configuration. The concentrated effluent generated during operation is not used in a separate reprocessing process or by diluting a certain proportion of the concentrated effluent with raw water, and the entire concentrated effluent is recovered and used, thereby eliminating the quantitative loss of feedwater and using a filter that comes to exhaustion method. Another object of the present invention is to provide a concentrated water treatment apparatus of a reverse osmosis facility capable of high-efficiency, high-recovery operation by improving the efficiency of the reverse osmosis membrane or the reverse osmosis membrane.

The present invention for achieving the above object, as a concentrated water treatment apparatus of a reverse osmosis facility for water treatment by reverse osmosis, the inlet portion 10 to which raw water is supplied; a pumping unit 20 installed downstream of the inlet unit 10 to pump raw water into input; a reverse osmosis filtration unit 30 installed downstream of the pumping unit 20 to filter raw water by reverse osmosis; a treated water outlet 40 connected to one downstream side of the reverse osmosis filtration unit 30 to discharge the treated water treated in the reverse osmosis filtration unit 30; a concentrated water discharge unit 50 connected to the other downstream of the reverse osmosis filtration unit 30 to discharge the concentrated water treated in the reverse osmosis filtration unit 30; And it is connected to the downstream of the concentrated water discharge unit 50 and the upstream of the pumping unit 20, respectively, to selectively recover the concentrated water discharged from the concentrated water discharge unit 50, the reverse osmosis filtration unit 30 ) to the recovery unit 60 for supplying; characterized in that it includes.

The inlet portion 10 of the present invention, a supply pipe for supplying by introducing raw water; a first pressure gauge installed on one side of the supply pipe to measure the pressure of raw water; a first water quality meter installed on one side of the supply pipe to measure the quality of raw water; a second water quality meter installed on the other side of the supply pipe to measure the quality of raw water; a potential analyzer installed on the other side of the supply pipe to measure raw water by a potential difference; and a silica analyzer installed on the other side of the supply pipe to measure raw water by silica.

The pumping unit 20 of the present invention includes a supply pump for pumping raw water into input; a pump controller connected to one side of the supply pump to control the pumping of the supply pump; and a second pressure gauge installed downstream of the supply pump to measure the pressure of the raw water.

The reverse osmosis filtration unit 30 of the present invention is characterized in that it consists of a filtration filter in which a plurality of reverse osmosis membranes are installed in a line inside the pressure vessel.

The reverse osmosis filtration unit 30 of the present invention consists of one or more filter groups in which a plurality of filtration filters are connected in multiple stages, and the one or more filter groups are arranged in series.

The reverse osmosis filtration unit 30 of the present invention consists of one or more filter groups in which a plurality of filtration filters are connected in multiple stages, and the one or more filter groups are arranged in parallel.

The treated water outlet 40 of the present invention includes: an outlet pipe through which the treated water flows out; a fourth water quality meter installed on one side of the outlet pipe to measure the water quality of the treated water; and a first flow meter installed on one side of the outlet pipe to measure the flow rate of treated water.

The concentrated water discharge unit 50 of the present invention, a first discharge pipe through which the concentrated water is discharged; a second discharge pipe branched to one side downstream of the first discharge pipe to discharge concentrated water to the outside; a first automatic valve installed on one side of the second discharge pipe to control whether or not the concentrated water is discharged; a third flow meter installed on one side of the second discharge pipe to measure the flow rate of concentrated water; and a fifth water quality meter installed on one side of the second discharge pipe to measure the quality of the concentrated water.

The recovery unit 60 of the present invention includes a recovery pipe for recovering concentrated water; a second automatic valve installed on one side of the recovery pipe to control whether or not the concentrated water is recovered; a first control valve installed at one side of the recovery pipe to control the recovery amount of concentrated water; a third pressure gauge installed on one side of the recovery pipe and installed upstream of the second automatic valve to measure the pressure of concentrated water; a second flow meter installed on the other side of the recovery pipe to measure the flow rate of concentrated water; a third water quality meter installed on the other side of the recovery pipe to measure the water quality of the concentrated water; and a fourth pressure gauge installed on the other side of the recovery pipe and installed upstream of the second flow meter to measure the pressure of the concentrated water.

In the pumping unit 20 of the present invention, the difference between the pressure measured downstream of the pumping unit 20 and the pressure measured by the third pressure gauge of the recovery unit 60 is equal to or greater than the set value. It is characterized in that the operation is stopped in a large case.

As described above, the present invention does not use concentrated wastewater that is simultaneously generated during the production of treated water by mixing and diluting it in a separate reprocessing process or feedwater at a certain ratio, and it is possible to produce treated water without discharging concentrated water during operation. When the set time or water quality is reached, only the water in the filter container is automatically discharged, providing the effect of enabling economical, high-efficiency, high-recovery operation without deterioration of the filter or reverse osmosis membrane.

In addition, by recovering the entire amount without discharging concentrated water during operation, the flow rate in the filter container is improved, and scale adhesion is suppressed on the filter surface due to concentration polarization. It provides the effect of improving the durability of the filter or reverse osmosis membrane by reducing

In addition, it is operated as drawn out to solve problems such as increase in operating cost, such as shortening the lifespan of the filter by minimizing the contamination caused by the imbalance of the filter or reverse osmosis membrane accompanying the quantitative loss of the feed water due to the concentrated effluent compared to the production water and the arrangement configuration. It does not use a separate reprocessing process or dilutes the concentrated effluent at a certain ratio with raw water, and recovers and uses the entire concentrated effluent, thereby eliminating the quantitative loss of feedwater and reducing the amount of wastewater in the filter or reverse osmosis membrane. By improving the efficiency, it provides the effect of high-efficiency, high-recovery operation.

1 is a block diagram showing the operating state of the concentrated water treatment apparatus of the reverse osmosis facility according to a first embodiment of the present invention.
Figure 2 is a block diagram showing the discharge state of the concentrated water treatment apparatus of the reverse osmosis facility according to the first embodiment of the present invention.
Figure 3 is a block diagram showing the operating state of the concentrated water treatment apparatus of the reverse osmosis facility according to the second embodiment of the present invention.
Figure 4 is a block diagram showing the discharge state of the concentrated water treatment apparatus of the reverse osmosis facility according to the second embodiment of the present invention.
Figure 5 is a block diagram showing the operating state of the concentrated water treatment apparatus of the reverse osmosis facility according to the third embodiment of the present invention.
Figure 6 is a block diagram showing the discharge state of the concentrated water treatment apparatus of the reverse osmosis facility according to the third embodiment of the present invention.
7 is a flowchart showing a treatment process of the concentrated water treatment apparatus of the reverse osmosis facility of the present invention.

Hereinafter, a preferred embodiment of the present invention will be described in more detail with reference to the accompanying drawings.

1 is a block diagram showing the operation state of the concentrated water treatment apparatus of the reverse osmosis facility according to the first embodiment of the present invention, Figure 2 is the concentrated water treatment apparatus of the reverse osmosis facility according to the first embodiment of the present invention. It is a configuration diagram showing the discharge state, Figure 3 is a configuration diagram showing the operating state of the concentrated water treatment apparatus of the reverse osmosis facility according to the second embodiment of the present invention, Figure 4 is reverse osmosis according to the second embodiment of the present invention It is a block diagram showing the discharge state of the concentrated water treatment apparatus of the irrigation facility, Figure 5 is a block diagram showing the operating state of the concentrated water treatment apparatus of the reverse osmosis facility according to the third embodiment of the present invention, Figure 6 is the present invention is a configuration diagram showing the discharge state of the concentrated water treatment device of the reverse osmosis facility according to the third embodiment of the present invention, Figure 7 is a flow chart showing the treatment process of the concentrated water treatment device of the reverse osmosis facility of the present invention.

1 and 2, the concentrated water treatment apparatus of the reverse osmosis facility according to this embodiment includes an inlet 10, a pumping unit 20, a reverse osmosis filtration unit 30, and a treated water outlet ( 40), the concentrated water discharge unit 50 and the recovery unit 60 are included, and is a concentrated water treatment device of a reverse osmosis facility for water treatment by reverse osmosis.

The inlet 10 is an inlet means to which raw water is supplied, and a supply pipe 11, a first pressure gauge 12, a first water quality meter 13, a second water quality meter 14, an electric potential meter 15, It consists of a silica analyzer (16).

The supply pipe 11 is a piping member for introducing and supplying raw water, and is connected downstream from a storage tank or a supply source of raw water for storing various raw water such as waste water, sewage water, and water supply to supply raw water.

The first pressure gauge 12 is a measuring member installed on one side of the supply pipe 11 to measure the pressure of raw water, and is made of a PT (PRESSURE TRANSMITTER) to measure the supply pressure of raw water and a treatment process by reverse osmosis of raw water The process pressure is adjusted to keep the process pressure constant.

The first water quality meter 13 is installed on one side of the supply pipe 11 and is a measuring member for measuring the quality of raw water.

The second water quality meter 14 is a measuring member installed on the other side of the supply pipe 11 to measure the quality of raw water, and is a TDS (Total Dissolved Solid) measuring device installed downstream of the junction of the raw water and the recovered concentrated water. The contamination level of the mixed water of raw water and concentrated water is measured during water treatment.

The potentiometer 15 is a measuring member installed on the other side of the supply pipe 11 to measure raw water by a potential difference, and is an ORP (Oxidation Reduction Potential) measuring device installed downstream of the junction of raw water and recovered concentrated water. The oxidation-reduction potential of the mixed water of raw water and concentrated water is measured during water treatment.

The silica analyzer 16 is installed on the other side of the supply pipe 11 and is a measuring member for measuring raw water by silica, and is installed downstream of the junction of raw water and recovered concentrated water. SiO ₂ (silicon dioxide; silica) It consists of a measuring instrument to measure the contamination level of the mixed water of raw water and concentrated water during water treatment.

The pumping unit 20 is installed downstream of the inlet unit 10 and is a pumping means for pumping raw water into the input pipe 21 , the supply pump 22 , the pump controller 23 , and the second pressure gauge 24 . ) consists of

The input pipe 21 is a piping member that is connected between the downstream of the supply pump 22 and the upstream of the reverse osmosis filtration unit 30 and injects raw water by pumping. It is supplied to the permeation filtration unit (30).

The supply pump 22 is an input member for pumping and inputting raw water, and supplies various raw water such as wastewater, sewage, and feedwater to the reverse osmosis filtration unit 30 by pumping the supply pump 22 .

The pump controller 23 is a controller connected to one side of the supply pump 22 to control the pumping of the supply pump 22, and consists of a VFD (Variable Frequency Drive) inverter and uses a voltage proportional to the frequency. 22) starts the motor.

The second pressure gauge 24 is installed downstream of the supply pump 22 and is a measuring member for measuring the pressure of raw water. is adjusted to keep the pumping pressure constant.

In addition, in this pumping unit 20, the difference between the pressure measured by the second pressure gauge 24 downstream of the pumping unit 20 and the pressure measured by the third pressure gauge 67 of the recovery unit 60 is set. It is preferable that the operation of the supply pump 22 is stopped when the value is equal to or greater than the set value.

The reverse osmosis filtration unit 30 is installed downstream of the pumping unit 20 and is a reverse osmosis filtration means for filtering raw water by reverse osmosis. A filtration filter in which a plurality of reverse osmosis membranes are installed in a line inside the pressure vessel consists of

In particular, the arrangement method of the reverse osmosis filtration unit 30 is largely divided into a first arrangement method, a second arrangement method, and a third arrangement method according to the arrangement method, and the first arrangement method is mainly used in household water purifiers, small capacity water treatment devices, and seawater desalination. In the case of seawater desalination, a single array method is used because of the high salt concentration of seawater, and a large amount of concentrated water, that is, about 50% of the feed water is discharged.

Therefore, the two-array method and three-array method are selectively used in the case of medium and large capacity and are determined according to the quality of raw water and the pretreatment method. The composition ratio of the pressure vessel is preferably 4: 2: 1 ratio is used.

In addition, the reverse osmosis filtration unit 30, as shown in Figs. 3 and 4, a plurality of filtration filters such as the 11th to 14th filtration filters (31a, 31b, 31c, 31d) are connected in multiple stages at least one It goes without saying that it is possible to consist of a filter group. It goes without saying that such one or more filter groups may be arranged in series.

In particular, the reverse osmosis filtration unit 30, as shown in Figs. 5 and 6, the eleventh to fourteenth filter filters (31a, 31b, 31c, 31d) and the twenty-first to twenty-fourth filter filters (32a, 32b, 32c) , 32d), etc., a plurality of filtration filters are formed of one or more filter groups connected in multiple stages, and of course, it is also possible that these one or more filter groups are arranged in parallel.

The treated water outlet 40 is connected to one downstream side of the reverse osmosis filtration unit 30 and is a treated water outlet means for discharging the treated water treated in the reverse osmosis filtration unit 30, the outlet pipe 41, the first 4 It consists of a water quality meter 42 and a first flow meter 43 .

The outflow pipe 41 is a piping member through which the treated water flows out from one downstream side of the reverse osmosis filtration unit 30 , and the treated water filtered by the reverse osmosis membrane from the reverse osmosis filtration unit 30 flows out.

The fourth water quality meter 42 is a measuring member installed on one side of the outlet pipe 41 to measure the water quality of the treated water, and consists of a Total Dissolved Solid (TDS) meter installed downstream of the reverse osmosis filtration unit 30 . Pollution degree of treated water discharged during water treatment is measured.

The first flow meter 43 is a measuring member installed on one side of the outlet pipe 41 to measure the flow rate of treated water, and is composed of an FT (FLOW TRANSMITTER) installed downstream of the reverse osmosis filtration unit 30 to treat water. By measuring the flow rate of the discharged treated water, the outflow amount of the treated water is maintained constant.

The concentrated water discharge unit 50 is connected to the other downstream side of the reverse osmosis filtration unit 30 to discharge the concentrated water treated by the reverse osmosis filtration unit 30 as a concentrated water discharging means, a first discharge pipe (51) , a second discharge pipe 52 , a first automatic valve 53 , a third flow meter 54 , and a fifth water quality meter 55 .

The first discharge pipe 51 is a piping member through which the concentrated water is discharged, and is connected to the other downstream of the reverse osmosis filtration unit 30 and the concentrated water filtered by the reverse osmosis membrane in the reverse osmosis filtration unit 30 is discharged.

The second discharge pipe 52 is a piping member for discharging concentrated water to the outside by branching on one side downstream of the first discharge pipe 51 , and the concentrated water filtered by the reverse osmosis membrane in the reverse osmosis filtration unit 30 . Some are selectively discharged to the outside.

The first automatic valve 53 is a valve member installed on one side of the second discharge pipe 52 to control whether or not the concentrated water is discharged. will be regulated

The third flow meter 54 is a measuring member installed on one side of the second discharge pipe 52 to measure the flow rate of concentrated water, and is composed of a FT (FLOW TRANSMITTER) installed downstream of the reverse osmosis filtration unit 30 . By measuring the flow rate of concentrated water discharged to the outside during water treatment, the discharge of concentrated water is kept constant.

The fifth water quality meter 55 is a measuring member installed on one side of the second discharge pipe 52 to measure the water quality of the concentrated water, and a TDS (Total Dissolved Solid) meter installed downstream of the reverse osmosis filtration unit 30 . The contamination level of the concentrated water discharged to the outside during water treatment is measured.

The recovery unit 60 is connected to the downstream of the concentrated water discharge unit 50 and the upstream of the pumping unit 20, respectively, to selectively recover the concentrated water discharged from the concentrated water discharge unit 50, and a reverse osmosis filtration unit ( 30) as a recovery means for supplying to, a recovery pipe 61, a second automatic valve 62, a first control valve 63, a third water quality meter 64, a second flow meter 65, a fourth pressure gauge 66 , a third pressure gauge 67 , a check valve 68 and a gate valve 69 .

The recovery pipe 61 is a piping member for recovering concentrated water, and is connected between the downstream of the concentrated water discharge unit 50 and the upstream of the pumping unit 20 to collect the concentrated water discharged from the reverse osmosis filtration unit 30 . Without discharging to the outside, it is merged with raw water downstream of the inlet 10 and reprocessed in the reverse osmosis filtration unit 30 to circulate and reprocess without discharging the concentrated water.

The second automatic valve 62 is a valve member installed on one side of the recovery pipe 61 to control whether the concentrated water is recovered, and is composed of a differential pressure flow control valve to selectively control whether the concentrated water is recovered.

The first control valve 63 is a valve member installed on one side of the recovery pipe 61 to control the recovery amount of concentrated water, and is composed of a solenoid valve to control the recovery amount of concentrated water that is mixed with raw water and reprocessed. do.

The third water quality meter 64 is a measuring member installed on the other side of the recovery pipe 61 to measure the water quality of the concentrated water, and consists of a TDS (Total Dissolved Solid) meter installed downstream of the reverse osmosis filtration unit 30 . It is selectively recovered during water treatment, mixed with raw water, and then re-treated to measure the contamination level of the circulating concentrated water.

The second flow meter 65 is a measuring member installed on the other side of the recovery pipe 61 to measure the flow rate of concentrated water. After being selectively recovered and mixed with raw water, the flow rate of the reprocessed and circulated concentrated water is measured to maintain a constant recovery amount of the concentrated water.

The fourth pressure gauge 66 is installed on the other side of the recovery pipe 61 and installed upstream of the second flow meter 65 to measure the pressure of the concentrated water. By measuring the recovery pressure of the concentrated water is adjusted to maintain a constant recovery pressure.

The third pressure gauge 67 is a measuring member installed on one side of the recovery pipe 61 and installed upstream of the second automatic valve 62 to measure the pressure of the concentrated water, and is composed of a PT (PRESSURE TRANSMITTER). By measuring the discharge pressure, it is adjusted to keep the discharge pressure of the concentrated water constant.

As such, when the difference between the pressure measured by the second pressure gauge 24 of the pumping unit 20 and the pressure measured by the third pressure gauge 67 of the recovery unit 60 is the same as the set value or greater than the set value Since the pressure of the mixed water of the raw water and the concentrated water rises than the pressure of the concentrated water, the membrane filtration efficiency by reverse osmosis is lowered, so it is preferable to stop the operation of the pumping unit 20 .

The check valve 68 is a valve member installed on one side of the recovery pipe 61 and installed downstream of the first control valve 63 to control the flow direction of the concentrated water. ) and the pumping unit 20 is controlled to flow in one direction only to the junction.

The gate valve 69 is a valve member installed on one side of the recovery pipe 61 and installed downstream of the first control valve 63 to control the recovery amount of concentrated water, and is mixed with the raw water of the inlet 10 . In this case, the flow rate of the concentrated water is controlled to adjust the recovery amount of the concentrated water according to various conditions such as water quality or hydraulic pressure of the raw water.

Hereinafter, a water treatment process using the concentrated water treatment apparatus of the reverse osmosis facility of this embodiment will be described in detail with reference to the drawings.

1, 2 and 7, the water treatment process using the concentrated water treatment apparatus of the reverse osmosis facility of this embodiment is, as shown in FIG. 7, the second automatic valve opening step (S10), the control valve opening Step (S20), pump operation step (S30), operation time setting step (S40), silica analysis step (S50), potential measurement step (S60), water quality measurement step (S70), pressure difference comparison step (S80), pump Stop step (S90), first automatic valve opening step (S100), valve closing step (S110), stop time setting step (S120), water quality analysis step (S130), valve control step (S140), pump control step (S150) ), and a pressure comparison step (S160), which is a concentrated water treatment process of a reverse osmosis facility for water treatment by reverse osmosis.

In the second automatic valve opening step (S10), part or all of the concentrated water is opened by opening the second automatic valve 62 installed in the recovery pipe 61 of the recovery part 60 branched from the concentrated water discharge part 50. As a step of recovering, the first automatic valve 53 of the concentrated water discharge unit 50 is closed and the second automatic valve 62 is opened to recover all the concentrated water discharged from the concentrated water discharge unit 50 Of course it is also possible.

The control valve opening step ( S20 ) is a step of opening the first control valve 63 installed downstream of the second automatic valve 62 , and the amount of opening of the first control valve 63 is adjusted to return the concentrated water. quantity will be adjusted.

In the pump operation step (S30), the pumping unit 20 installed downstream of the confluence of the inlet 10 through which the raw water is introduced and the recovery unit 60 in which the concentrated water discharged from the reverse osmosis filtration unit 30 is recovered. As a step of operation, the pumping unit 20 is operated to pump the mixed water of raw water and concentrated water, and it is put into the reverse osmosis filtration unit 30 .

The operation time setting step (S40) is a step of setting the operation time of the pumping unit 20, comparing the service time and the set time, which are the operation time of the pumping unit 20, for the mixed water of raw water and concentrated water. By measuring the flow state such as flow rate or pressure, the operation time of the pumping unit 20 is determined to control whether the pump is operated.

In the silica analysis step (S50), the silica analyzer 16 installed downstream of the confluence of the inlet 10 into which the raw water is introduced and the recovery unit 60 in which the concentrated water discharged from the reverse osmosis filtration unit 30 is recovered. As a step of analyzing by the silica analyzer 16, the silica contained in the mixed water of the raw water and the concentrated water is analyzed and compared with a set value to control whether the pump is driven.

In the potential measuring step (S60), the potentiometer 15 installed downstream of the confluence of the inlet 10 through which raw water is introduced and the recovery unit 60 in which the concentrated water discharged from the reverse osmosis filtration unit 30 is recovered. As a step of analyzing by the potentiometer 15, the potential difference of the mixed water of the raw water and the concentrated water is analyzed and compared with a set value to control whether the pump is driven.

In the water quality measurement step (S70), a second water quality meter 14 installed downstream of the confluence of the inlet 10 through which the raw water is introduced and the recovery unit 60 in which the concentrated water discharged from the reverse osmosis filtration unit 30 is recovered. ), the second water quality meter 14 analyzes the contamination level of the mixed water of the raw water and the concentrated water and compares it with a set value to control whether the pump is driven.

In the pressure difference comparison step (S80), the difference between the pressure measured by the second pressure gauge 24 of the pumping unit 20 and the pressure measured by the third pressure gauge 67 of the recovery unit 60 is compared with a set value. When the difference value is the same as the set value or greater than the set value, the pressure of the mixed water of the raw water and the concentrated water rises than the pressure of the concentrated water, so that the membrane filtration efficiency by reverse osmosis is lowered, so that the pumping unit 20 ), it is desirable to stop the operation.

The pump stop step (S90), the operation time setting step (S40), the silica analysis step (S50), the potential measurement step (S60), the water quality measurement step (S70), and the pressure difference comparison step (S80) according to the determination result As a step of stopping the pump, the state of the pressure, water quality, potential difference, etc. of the mixed water of the raw water and the concentrated water rises above the set value, so that the membrane filtration efficiency by reverse osmosis is lowered, so that the operation of the pumping unit 20 is stopped. do.

The first automatic valve opening step (S100) is a step of opening the first automatic valve 53 installed in the concentrated water discharge unit 50, and when the pumping unit 20 is stopped in the pump stop step (S90) The first automatic valve 53 is opened to discharge concentrated water to the outside.

The valve closing step ( S110 ) is a step of closing the second automatic valve 62 and the first control valve 63 installed in the recovery unit 60 , and closing the recovery unit 60 to discharge concentrated water and concentrated water. By flowing only in the portion 50, the entire concentrated water is discharged to the outside.

The stop time setting step (S120) is a step of setting the stop time of the pumping unit 20, comparing the set time with the service time, which is the stop time of the pumping unit 20, to the mixed water of raw water and concentrated water. By measuring the flow state such as flow rate or pressure, the stop time of the pumping unit 20 is determined to control whether the pump is operated.

The water quality analysis step (S130) is a step of analyzing the water quality by the fourth water quality meter 42 installed downstream of the drainage site where the treated water discharged from the reverse osmosis filtration unit 30 is discharged, and the fourth water quality meter 42 ), the degree of contamination of the treated water is analyzed and compared with the set value to control whether the pump is driven or not.

The valve control step (S140) is a step of controlling whether the first control valve 63 installed in the recovery unit 60 is opened, and the first control valve 63 is opened by PID control (Proportional Integral Derivation Control). By adjusting the amount, the recovery amount of the concentrated water is controlled.

The pump control step (S150) is a step of controlling whether the supply pump 22 installed in the pumping unit 20 operates, and by controlling whether the supply pump 22 is operated by PID control (Proportional Integral Derivation Control). The input amount of the mixed water of raw water and concentrated water is adjusted.

The pressure comparison step (S160) is a comparison step of comparing the pressure measured by the first pressure gauge 12 installed in the inlet 10 with 1.5 times the atmospheric pressure, and the measured pressure of the first pressure gauge 12 is 1.5 of the atmospheric pressure. When it is larger than twice the size, the input amount of the mixed water of raw water and concentrated water is adjusted by controlling whether the supply pump 22 is operated.

In addition, the concentrated water treatment apparatus of the reverse osmosis facility of the present invention is a high-pressure pump and a pressure vessel equipped with a plurality of pressure vessels connecting four or less filters or reverse osmosis membranes in series and an inlet inverter to be distributed within one pressure vessel. It consists of an internal water discharge valve, a water quality meter, and a recovery pipe from a plurality of filters, and the operation time is 25 to 50 minutes to produce treated water without discharging concentrated water. Only the water in the filter in the filter container is discharged for 1 to 2 minutes.

As described above, according to the present invention, the concentrated wastewater generated at the same time during the production of treated water is not used in a separate reprocessing process or mixed and diluted in feed water at a certain ratio, and treated water can be produced without discharging concentrated water during operation. When the set time or water quality is reached, only the water in the filter container is automatically discharged, providing the effect of enabling economical, high-efficiency, high-recovery operation without degradation of the filter or reverse osmosis membrane.

In addition, by recovering the entire amount without discharging concentrated water during operation, the flow rate in the filter container is improved, and scale adhesion is suppressed on the filter surface due to concentration polarization. It provides the effect of improving the durability of the filter or reverse osmosis membrane by reducing

In addition, it is operated as drawn out to solve problems such as increase in operating costs such as shortening the lifespan of the filter by minimizing the contamination caused by the imbalance of the filter or reverse osmosis membrane accompanying the quantitative loss of the feed water due to the concentrated effluent compared to the production water and the arrangement configuration. It does not use a separate reprocessing process or dilutes the concentrated effluent with raw water at a certain ratio, and recovers and uses the entire concentrated effluent, thereby eliminating the quantitative loss of feedwater and reducing the amount of wastewater in the filter or reverse osmosis membrane. By improving the efficiency, it provides the effect of high-efficiency, high-recovery operation.

The present invention described above can be embodied in various other forms without departing from the technical spirit or main characteristics thereof. Accordingly, the above embodiments are merely examples in all respects and should not be construed as limiting.

10: inlet 20: pumping unit
30: reverse osmosis filtration unit 40: treated water outlet
50: concentrated water discharge unit 60: recovery unit

Claims (10)

As a concentrated water treatment device of a reverse osmosis facility for water treatment by reverse osmosis,
an inlet 10 to which raw water is supplied;
a pumping unit 20 installed downstream of the inlet unit 10 to pump raw water into input;
a reverse osmosis filtration unit 30 installed downstream of the pumping unit 20 to filter raw water by reverse osmosis;
a treated water outlet 40 connected to one downstream side of the reverse osmosis filtration unit 30 to discharge the treated water treated in the reverse osmosis filtration unit 30;
a concentrated water discharge unit 50 connected to the other downstream of the reverse osmosis filtration unit 30 to discharge the concentrated water treated in the reverse osmosis filtration unit 30; and
It is connected to the downstream of the concentrated water discharge unit 50 and the upstream of the pumping unit 20, respectively, to selectively recover the concentrated water discharged from the concentrated water discharge unit 50, and the reverse osmosis filtration unit 30 Includes; recovery unit 60 for supplying to
The recovery unit 60,
a recovery pipe for recovering concentrated water;
a second automatic valve installed on one side of the recovery pipe to control whether or not the concentrated water is recovered;
a first control valve installed at one side of the recovery pipe to control the recovery amount of concentrated water;
a third pressure gauge installed on one side of the recovery pipe and installed upstream of the second automatic valve to measure the pressure of concentrated water;
a second flow meter installed on the other side of the recovery pipe to measure the flow rate of concentrated water;
a third water quality meter installed on the other side of the recovery pipe to measure the water quality of the concentrated water; and
Concentrated water treatment apparatus of a reverse osmosis facility comprising a; a fourth pressure gauge installed on the other side of the recovery pipe and installed upstream of the second flow meter to measure the pressure of the concentrated water. The method of claim 1,
The inlet 10 is,
a supply pipe for introducing and supplying raw water;
a first pressure gauge installed on one side of the supply pipe to measure the pressure of raw water;
a first water quality meter installed on one side of the supply pipe to measure the quality of raw water;
a second water quality meter installed on the other side of the supply pipe to measure the quality of raw water;
a potential analyzer installed on the other side of the supply pipe to measure raw water by a potential difference; and
Concentrated water treatment apparatus of a reverse osmosis facility comprising a; a silica analyzer installed on the other side of the supply pipe to measure raw water by silica. The method of claim 1,
The pumping unit 20,
a supply pump for pumping and inputting raw water;
a pump controller connected to one side of the supply pump to control the pumping of the supply pump; and
Concentrated water treatment apparatus of a reverse osmosis facility comprising a; a second pressure gauge installed downstream of the supply pump to measure the pressure of the raw water. The method of claim 1,
The reverse osmosis filtration unit 30 is a concentrated water treatment apparatus of a reverse osmosis facility, characterized in that it consists of a filtration filter in which a plurality of reverse osmosis membranes are installed in a line inside the pressure vessel. The method of claim 1,
The reverse osmosis filtration unit 30 is composed of one or more filter groups in which a plurality of filtration filters are connected in multiple stages, and the one or more filter groups are arranged in series. Device. The method of claim 1,
The reverse osmosis filtration unit 30 is composed of one or more filter groups in which a plurality of filtration filters are connected in multiple stages, and the one or more filter groups are arranged in parallel. Device. The method of claim 1,
The treated water outlet 40,
Outflow pipe through which treated water flows out;
a fourth water quality meter installed on one side of the outlet pipe to measure the water quality of the treated water; and
Concentrated water treatment apparatus of a reverse osmosis facility comprising a; a first flow meter installed on one side of the outlet pipe to measure the flow rate of the treated water. The method of claim 1,
The concentrated water discharge unit 50,
a first discharge pipe through which concentrated water is discharged;
a second discharge pipe branched to one side downstream of the first discharge pipe to discharge concentrated water to the outside;
a first automatic valve installed on one side of the second discharge pipe to control whether or not the concentrated water is discharged;
a third flow meter installed on one side of the second discharge pipe to measure the flow rate of concentrated water; and
Concentrated water treatment apparatus of a reverse osmosis facility comprising a; a fifth water quality meter installed on one side of the second discharge pipe to measure the water quality of the concentrated water. delete The method of claim 1,
The pumping unit 20, when the difference between the pressure measured downstream of the pumping unit 20 and the pressure measured by the third pressure gauge of the recovery unit 60 is equal to or greater than the set value Concentrated water treatment device of a reverse osmosis facility, characterized in that the operation is stopped.

Images