KR101558335B1 - Desalination device - Google Patents

Abstract

The present invention provides a seawater desalination apparatus which implements a preprocessing apparatus by using a non-chemical method, and is easy to use. According to the present invention, the seawater desalination apparatus includes: a storage tank storing seawater; a main pipe conveying the seawater in the storage tank; a first preprocessing unit which processes the microorganisms and foreign substances in the seawater conveyed through the main pipe; a second preprocessing unit which adds bubbles to the seawater processed by the first preprocessing unit through the main pipe, enables aeration therein, and converts the seawater to magnetic water; a separation unit removing the salt in the seawater processed by the second preprocessing unit; and a post-processing unit which performs an additional sterilizing operation on the fresh water generated through the separation unit.

Description

Desalination device

The present invention relates to a desalination apparatus, and more particularly, to a desalination apparatus for desalinating sea water using a membrane separation method.

In countries lacking water, drinking water is being produced using desalination facilities that desalinate seawater. The desalination facilities are largely divided into a distillation method and a membrane separation method. The distillation method is a method for producing drinking water by condensing the evaporated water after evaporating the seawater. The membrane separation method is a method for separating drinking water from seawater using a membrane, And reverse osmosis.

A number of devices using the above method have been proposed. For example, in patent No. 659375, heating or room temperature seawater is atomized by a spraying device, and atomized sea water is contacted with air as a carrier so that only water in the seawater is humidified by air to desalinate, A structure of a seawater desalination apparatus by a distillation method for condensing water is disclosed.

Also, in the registered patent No. 1133046, a desalination tank made of a heat insulating material and forming a certain space therein; A solar module provided outside the desalination tank for absorbing solar heat to heat the heating medium; A heating medium circulation line provided below the inside of the desalination tank and through which the heating medium heated by the solar module circulates; A seawater supply module for supplying seawater to the desalination tank; A desalination module provided on the inside of the desalination tank and condensing water vapor evaporated in the seawater by the heat medium circulation line to become fresh water; And a fresh water storage tank for discharging and storing the fresh water produced in connection with the desalination module to the outside, and a seawater desalination apparatus using the distillation method.

On the other hand, a desalination apparatus using a membrane separation method is disclosed in Japanese Patent Registration No. 971499. The patent discloses a method for sterilizing microorganisms contained in seawater through the pretreatment unit, comprising the steps of: a water intake part for taking seawater; an organic matter, a colloid, and a microorganism contained in the seawater; And a reverse osmosis membrane that is operative to produce fresh water from the seawater passing through the microbial sterilizing unit, wherein the microbial sterilizer is composed of a chlorine disinfection unit and an ultraviolet ray disposing unit sequentially disposed, and the chlorine disinfection unit The processing unit is operative to remove microorganisms in the seawater by injecting chlorine into the seawater, and the ultraviolet treatment unit performs a role of removing microorganisms in the seawater by using an ultraviolet lamp.

As described above, in the case of the distillation method, the seawater desalination apparatus has a disadvantage in that relatively high energy cost is consumed by separating the drinking water by evaporating the water by a separate heating source and then condensing the separated water. There is a disadvantage in that a number of devices for sterilizing energy and also seawater are added and have a somewhat complicated configuration. Particularly, in the case of the membrane separation method, a chemical pretreatment process such as chlorine disinfection is required, which requires a large-scale pretreatment facility and a complication in use due to chemical treatment. Thus, a new method of performing a sterilization process with a simple pretreatment device Of the seawater desalination apparatus.

The present invention has been conceived to overcome the disadvantages of the separation membrane type seawater desalination apparatus as described above, and it is an object of the present invention to provide a seawater desalination apparatus which is easy to use by implementing a pretreatment apparatus in a nonchemical manner.

According to an aspect of the present invention, there is provided a desalination apparatus for desalinating seawater, comprising: a storage tank for storing seawater; A main pipe for transferring the seawater of the storage tank; A first pretreatment unit for treating microorganisms and foreign matter of seawater transferred through the main pipe; A second pre-processing unit for adding bubbles to the seawater processed by the first pre-processing unit through the main pipe, forming an aeration, and then converting the bubbles into magnetized water; A separator for removing salt of the seawater processed in the second pretreatment unit; And a post-treatment unit for performing an additional sterilization on the fresh water produced through the separation unit.

Preferably, the first pretreatment unit includes: a magnetizer for converting seawater into a magnetized water to move the main pipe; An ultrasonic device for destroying the microorganisms of the seawater; A scale removing device for suppressing scale generation of the pipe; And a water purifier for removing foreign matter from the seawater.

More preferably, the water purifier is composed of a large gravel layer, a small gravel layer, a sand layer, an activated carbon layer and a ceramic layer in sequence.

Preferably, the second pre-processing section includes: a bubble generating device for supplying bubbles to the main pipe; A main valve that periodically opens and closes the main pipe; A vortex generating device for generating a vortex in the seawater having passed through the main valve; And an ion water treatment device for magnetizing seawater having passed through the vortex generating device.

Preferably, the separating unit further comprises a UV sterilizing unit for removing salt water from the seawater by a membrane separation method, and disinfecting the post-treatment unit using UV of the fresh water generated by the separating unit.

More preferably, the post-treatment unit further comprises a bobble section for providing bubbles to the fresh water.

Preferably, the bubble generating device communicates with the storage tank, and bubbles are supplied to the vortex generating device and the separating part, and the bubble generating device periodically carries out bubbles.

The desalination apparatus according to the present invention removes microorganisms through a pretreatment apparatus for pretreatment of seawater by means of a magnetizer, an ultrasonic generator, a bubble generator, etc., and periodically drives the pretreatment apparatus in a manner of automatically washing it, And it is also advantageous that it can be implemented as a small scale seawater desalination apparatus.

1 is a configuration diagram of a desalination apparatus according to the present invention,
Fig. 2 is a configuration diagram of the storage tank shown in Fig. 1,
Fig. 3 is a configuration diagram of the pretreatment apparatus shown in Fig. 1,
Fig. 4 is a configuration diagram of the water purifier shown in Fig. 3,
FIG. 5 is a configuration diagram of the separating unit and the post-processing unit shown in FIG. 1,
6 is a connection configuration diagram of the bubble generator shown in FIG.

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

1, the desalination apparatus 100 according to the present invention includes a storage tank 10 for storing seawater, a pretreatment unit 20 for pretreating the seawater of the storage tank 10, a pretreatment unit 20 A separation unit 70 for removing the salinity of the seawater treated through the separation unit 70, and a post-treatment unit 80 for further treating the fresh water separated through the separation unit 70.

2, the storage tank 10 serves to store seawater for desalination processing, a water tank filter 11 is disposed at a lower end of the water storage tank 10, 12).

The water tank filter 11 has a clearance for allowing general foreign matter to pass therethrough and prevents the movement of the sediment when the seawater is discharged to the discharge pipe 13 formed on the side surface.

The sucking unit 12 communicates with the discharge pipe 91. A waste pipe 14 is formed at the upper end of the discharge pipe 13 and the waste pipe 14 is connected to the first pre- And a separate valve communicating with the main pipe 22 between the first pre-treatment section 31 and the second pre-treatment section 31 for opening and closing the right pipe 14.

The storage tank 10 continuously receives seawater through a seawater pipe 19 formed at an upper end thereof.

Meanwhile, the seawater stored in the storage tank 10 moves to the pretreatment unit 20 through the discharge pipe 13.

At this time, a pump 15 is provided at the rear end of the discharge pipe 13 to pressurize the seawater.

3, the pretreatment unit 20 includes a main pipe 22, a magnetic sensor 23, an ultrasonic device 24, a descale device 25, and a water purifier 26, A first pretreatment unit 21 and a second pretreatment unit 31 including a main valve 32, a bubble generator 90, a vortex generator 34 and an ion water treatment unit 35.

The first pretreatment unit 21 serves to disinfect the seawater through the storage tank 10. The first pretreatment unit 21 includes a magnetizer 23, an ultrasonic device 24, a descale device 25, and a water purifier 26 .

The magnetizer 23 includes a permanent magnet having a total magnetic force of 6,000 to 8,000 gauss. The magnetizer 23 serves to magnetize the sea water flowing through the main pipe 22, and is constructed by applying a general magnetizing device.

The ultrasonic device 24 serves to sterilize the microorganisms contained in the seawater by applying ultrasonic waves to the seawater having passed through the magnetizer 23.

The scale removing device 25 plays a role of suppressing scale generation in the main pipe 22 or the like due to seawater, and a conventional scale removing device can also be applied.

As shown in FIG. 4, the water purifier 26 includes a cylindrical body, a plurality of material layers acting as a plurality of filters in the body, and a non- Thereby preventing movement of the material layer.

First, a large gravel layer is formed at the top, and the size of the large gravel is 20 to 30 mm.

A small gravel layer is formed at the lower end of the large gravel layer, and the size of the small gravel is 5 to 15 mm.

The initial constants can be efficiently performed in the above range.

A sand layer is formed at the lower end of the small gravel layer and an activated carbon layer formed of char or activated carbon is formed at the lower end of the sand layer.

In the material layer, a relatively large particle layer is located at the upper end and a smaller particle layer is located at the lower end.

Finally, a ceramic layer is formed. Since the ceramic layer plays a role of disinfection according to the far-infrared ray emission rather than the filtering role, the size of the ceramic particles can be selectively configured.

The water purifier 26 functions to remove foreign substances in the seawater and to filter the microorganisms killed by the ultrasonic waves.

The first pretreatment unit 21 functions to treat seawater for the first time, and microorganisms in the seawater are killed through ultrasonic waves, and then the foreign substances are filtered through the water purification unit.

Meanwhile, the seawater having passed through the first pretreatment unit 21 is secondarily treated through the second pretreatment unit 31.

The second pretreatment unit 31 includes a main valve 32, a bubble generator 33, a vortex generator 34, and an ion water treatment device 35.

The main valve 32 periodically opens and closes the main pipe 22.

Before the main valve 32, bubbles are introduced through the bubble generator 33. At this time, the bubbles introduced through the bubble generator 90 exhibit an effect of being raised by the opening / closing action of the main valve 32, thereby killing the remaining microorganisms and strongly stimulating the surfaces of the internal components, Thereby cleaning the inside of the component.

The bubbles are preferably formed of micro bubbles, but they may be mini bubbles if necessary.

At this time, the operation of the main valve 32 operates in conjunction with the operation of the bubble generator 33.

The main pipe (22) after the main valve (32) is branched into two and flows into the vortex generator (34).

The vortex generator 34 is a cylindrical body having an internal space formed therein. The body has a larger diameter than the main pipe 22, and an impingement plate is formed at the center thereof.

Therefore, the seawater introduced into the vortex generator 34 forms a large amount of air by the aeration action, and then is discharged to the two main pipes 22.

The seawater discharged from the vortex generator 34 is once again magnetized through the ion water cooling device 35 provided in each main pipe 22. [

The ion water conservation device 35 serves to magnetize seawater passing through the main pipe 22 with a magnetizer including a permanent magnet of 8,000 to 13,000 gauss, and provides an environment favorable for separation of salt water through the separation membrane.

The seawater treated through the first pretreatment unit 21 and the second pretreatment unit 32 finally removes the salt through the separation unit 70.

The separator 70 may have a structure as shown in FIG. 5, and may be realized by a reverse osmosis system or a separator system. The separator 70 has a conventional structure.

The seawater treated in the pretreatment unit 20 flows into the separator 70 through the two inflow parts and the desalted fresh water is discharged through the discharge port 71 and flows to the main pipe 22.

Further, the separating unit 70 is connected to the discharge pipe 91 through a seawater discharge unit 72 through which seawater having high salinity is discharged.

The fresh water generated through the separation unit 70 moves through the main pipe 22 and is finally treated through the post-treatment unit 80.

The post-treatment unit 80 is composed of a UV sterilizer 81 and a bubble unit 82. The UV sterilizer 81 irradiates fresh water with ultraviolet light to finally sterilize the bubble unit 82, The microbubbles are applied to fresh water to perform sterilization and contaminant removal at the same time.

If necessary, the bubble portion 82 may be omitted.

6, the bubble generator 90 is connected to the waste water pipe 14 to supply water to the water storage tank 10, if necessary, in addition to the function of continuously supplying the bubbles to the main pipe 22. [ It is possible to perform a cleaning function of introducing seawater having a bevel on the side surfaces of the vortex generator 34, the separator 70, the UV sterilizer 81,

The cleaning function is for cleaning the vortex generator 34, the separator 70, the UV sterilizer 81 and the bubble portion 82 and may be performed using the seawater of the storage tank 10, The fresh water can be supplied to the storage water tank 10 and the fresh water can be used to extend the lifespan of the entire desalination apparatus 100 when the water is periodically performed.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, And all of the various forms of embodiments that can be practiced without departing from the technical spirit.

10: Storage tank 11: Water tank filter
13: discharge pipe 14:
15: Pump 19: Sea water pipe
20: preprocessing unit 21: first preprocessing unit
22: main pipe 23:
24: Ultrasonic device 25: Scale removal device
26: Water purifier 31: Second pre-
32: main valve 34: vortex generator
35: ion water conservation device 70:
71: outlet 80: post-processor
81: UV sterilizer 82: bubble part
90: bubble generator 91: exhaust pipe
100: Desalination unit

Claims (7)

delete A desalination apparatus for desalinating seawater, comprising:
A storage tank for storing seawater;
A main pipe for transferring the seawater of the storage tank;
A first pretreatment unit for treating microorganisms and foreign matter of seawater transferred through the main pipe;
A second pre-processing unit for adding bubbles to the seawater processed by the first pre-processing unit through the main pipe, forming an aeration, and then converting the bubbles into magnetized water;
A separator for removing salt of the seawater processed in the second pretreatment unit; And
And a post-treatment unit for performing additional sterilization on fresh water caught by the separation unit,
The first preprocessor includes:
A magnetizer for converting the seawater which moves the main pipe into magnetized water;
An ultrasonic device for destroying the microorganisms of the seawater;
A scale removing device for suppressing scale generation of the pipe; And
And a water purifier for removing foreign matter from the seawater.
The desalination apparatus according to claim 2, wherein the water purifier is composed of a large gravel layer, a small gravel layer, a sand layer, an activated carbon layer, and a ceramic layer.
3. The apparatus of claim 2, wherein the second pre-
A bubble generator for supplying bubbles to the main pipe;
A main valve that periodically opens and closes the main pipe;
A vortex generating device for generating a vortex in the seawater having passed through the main valve; And
And an ion-conducting device for magnetizing seawater having passed through the vortex generating device.
[4] The desalting apparatus according to claim 2, wherein the separating unit further comprises a UV sterilizing unit for removing salt water from the seawater by a membrane separation method and disinfecting the post-treatment unit using UV of fresh water generated by the separating unit. .
[6] The desalination apparatus according to claim 5, wherein the post-treatment unit further comprises a bubble portion for providing a bubble to the fresh water.
[6] The desalination apparatus of claim 4, wherein the bubble generating device communicates with the storage tank, and bubbles are supplied to the vortex generating device and the separating device periodically.

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