KR101721203B1 - Desalination apparatus using solar thermal energy and waste heat - Google Patents

Abstract

A desalination apparatus using solar heat and waste heat according to an embodiment of the present invention includes a storage tank for storing seawater; A flow pipe installed in the reservoir to be in contact with the seawater; A reflection fin directly connected to the flow tube, the reflection fin including an upper fin protruding above the water surface of the seawater and a lower fin submerged below the water surface of the seawater; A permeable body installed on the storage tank and inclined at a predetermined angle with respect to the water surface of the seawater; And a collecting part installed at a lower side of the permeable body and in which seawater in the reservoir is evaporated and condensed in contact with the permeable body flows along the permeable body and is stored, Reflects the light and absorbs sunlight from the other surface, and the lower fin transfers the heat of the fluid flowing inside the flow tube to the seawater.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a desalination apparatus using solar heat and waste heat,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a desalination apparatus, and more particularly, to a desalination apparatus capable of desalinating seawater by using solar heat or waste heat of a power generation apparatus as a heat source.

There are many places in the world where power and water infrastructure are lacking at the same time, such as the island, remote areas, and developing countries.

In general, seawater desalination techniques include evaporation using water evaporation and membrane filtration using membranes. As the membrane filtration method, the reverse osmosis method is used. However, the reverse osmosis method has a problem that a large amount of electric energy is consumed and maintenance and repair are difficult.

The decompression method in the evaporation method is inadequate to be used in an area where energy supply and demand is difficult, such as a book site, because the initial construction cost and the maintenance cost are excessive.

In addition, when the sea water is evaporated and desalinated, the proportion of sunlight that is not used and reflected from the sea surface is high, so that the solar energy can not be used efficiently.

In addition, there is a problem of energy waste and environmental pollution because waste heat generated in a general power generation device is not used and is discarded.
The technique which is the background of the present invention is disclosed in Korean Patent Laid-Open Publication No. 10-2013-0141843 (Dec. 27, 2013).

Accordingly, the present invention can evaporate seawater using solar heat to desalinate it, and evaporate seawater through waste heat such as power and power generation equipment / facilities together with solar heat, and evaporate seawater continuously using evaporation heat of evaporated seawater So that it can be desalinated.

And to provide a desalination device capable of maximizing the efficiency of the seawater desalination by maximizing the efficiency of solar / solar energy that is not used and reflected from the sea surface when the seawater is evaporated through the solar heat.

A desalination apparatus using solar heat and waste heat according to an embodiment of the present invention includes: a storage tank for storing seawater; A flow pipe installed in the reservoir to be in contact with the seawater; A reflection fin directly connected to the flow tube, the reflection fin including an upper fin protruding above the water surface of the seawater and a lower fin submerged below the water surface of the seawater; A permeable body installed on the storage tank and inclined at a predetermined angle with respect to the water surface of the seawater; And a collecting part installed at a lower side of the permeable body and in which seawater in the reservoir is evaporated and condensed in contact with the permeable body flows along the permeable body and is stored, Reflects the light and absorbs sunlight from the other surface, and the lower fin transfers the heat of the fluid flowing inside the flow tube to the seawater.

The reflecting fin may be fixed to a groove formed on the surface of the flow tube.

The reflecting fin may be fixed to the flow tube by a connecting member.

The flow tube may include an inclined surface, and the reflective fin may be in contact with the inclined surface.

One surface of the upper fin is mirror-finished, and the one surface may be a surface on which sunlight passing through the transmitting body is incident.

The other surface of the upper fin faces the sea surface of the storage tank and can absorb sunlight reflected on the sea surface.

The other surface of the upper fin may be black coated.

The flow pipe may be a plurality of straight pipes which are in contact with the seawater of the storage tank, and a solar pipe and a waste heat which are located outside the storage tank and include a connection pipe connecting the straight pipes.

The desalination apparatus according to claim 1, further comprising: a plurality of desalination members installed adjacent to the storage tank, wherein each desalination member includes a plate installed upright, a seawater supply unit positioned on one upper surface of the plate,

A condensed water pocket positioned at a lower side of the plate and collecting condensed water,

And a wick attached to the other surface of the plate to absorb and flow seawater from the seawater supply unit.

One surface of the plate may be a surface on which sunlight reflected from one surface of the reflecting fin is incident.

If the fresh water system is installed as in the present invention, desalination of the seawater by using the waste heat of power and power installation and the heat of condensation of the seawater can reduce the energy wastage, and desalination of seawater at nighttime when solar heat is not available It is possible to increase productivity and efficiency.

Also, by providing the reflecting fin as in the present invention, it is possible to increase the solar heat transmitted to the fresh water member using the condensation heat, thereby increasing the productivity and efficiency.

In addition, as in the present invention, the reflection fin can be used as a heating source for seawater by absorbing solar heat reflected from the sea surface, thereby increasing the desalination efficiency.

In addition, if a desalination device capable of using solar heat and waste heat at the same time is installed as in the present invention, not only eco-friendly small-capacity desalination facilities for books, coastal areas and remote areas lacking electric power facilities or water facilities due to local and economic conditions, It can be utilized as a dispersion type small-scale desalination plant in an area where economical efficiency is secured in consideration of cost and high oil price.

Further, the present invention is simple in structure, thereby reducing initial construction cost and operating cost.

1 is a schematic perspective view of a fresh water system according to an embodiment of the present invention.
Figure 2 is a cross-sectional view of the flow tube and the reflective fin of the fresh water system of Figure 1;
3 is a top view of a flow tube of the fresh water system of FIG.
4 and 5 are cross-sectional views of a flow tube and a reflecting fin according to another embodiment of the present invention.
6 is a perspective view of a flow tube according to another embodiment of the present invention.
7 is a cross-sectional view of a flow tube and a reflective fin according to another embodiment of the present invention.
8 is a plan view of a flow tube according to another embodiment of the present invention.
9 is a sectional view of the fresh water member of the fresh water system of FIG.
10 is a view for explaining a process of desalinating seawater using the desalination apparatus according to the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings, which will be readily apparent to those skilled in the art to which the present invention pertains. The present invention may be embodied in many different forms and is not limited to the embodiments described herein.

In order to clearly illustrate the present invention, parts not related to the description are omitted, and the same or similar components are denoted by the same reference numerals throughout the specification.

Throughout the specification, when a part is referred to as being "connected" to another part, it includes not only "directly connected" but also "indirectly connected" between other parts. Also, when a part is referred to as "including " an element, it does not exclude other elements unless specifically stated otherwise.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to the preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings.

FIG. 1 is a schematic perspective view of a fresh water system according to an embodiment of the present invention, FIG. 2 is a sectional view of a flow tube and a reflection fin of the fresh water system of FIG. 1, FIG. 3 is a plan view of a flow tube of the fresh water system of FIG. FIG. 6 is a perspective view of a flow tube according to another embodiment of the present invention, and FIG. 7 is a cross-sectional view of a flow tube according to another embodiment of the present invention. And FIG. 8 is a plan view of a flow pipe according to another embodiment of the present invention, and FIG. 9 is a sectional view of a fresh water member of the fresh water apparatus of FIG.

As shown in FIG. 1, a desalination apparatus 1000 according to the present invention includes a first fresh water section 100 and a second fresh water section 200 for evaporating seawater to desalinate.

The first fresh water section 100 and the second fresh water section 200 heat the seawater using solar heat and collect the generated fresh water by condensing the generated water vapor.

The first fresh water section 100 includes a reservoir 10 for storing seawater W1, a permeable body 20 for transmitting sunlight and a water collecting tank 30 for collecting fresh water W2.

The storage tank 10 is installed below the first fresh water section 100, and the seawater W1 is stored.

The permeable body 20 is disposed at an upper portion of the storage tank 10, away from the storage tank 10. The transmission body 20 may be formed of a transparent material through which sunlight (solar radiation energy) can be transmitted, for example, glass or a transparent polymer material.

The permeable body 20 is inclined at a constant angle with respect to the sea surface of the storage tank 10. The inclination angle alpha of the permeable body 20 can be variously adjusted according to the seasonal and latitude of the target area where the fresh water supply device of the present invention is installed according to the embodiment of the user.

The storage tank 10 is provided with a flow tube 14 through which a fluid such as an exhaust gas can move and a reflecting fin 16 connected with the flow tube 14.

Referring specifically to Figure 2, the flowtube 14 is installed such that at least a portion of the flowtube 14 is submerged in seawater stored in the reservoir 10 and the flowtube 14 is in contact with the seawater. As shown in FIG. 3, the flow tubes 14 may be arranged in various forms at regular intervals for uniform heat transfer to the seawater of the storage tank, for example, in a zigzag form. The exhaust gas discharged from the power generation / electric power facility 80 of the installation area where the fresh water system of the present invention is installed can flow into the flow pipe 14.

The reflecting fin 16 can be connected to the plate member in a longitudinal direction of the flow tube 14.

The reflecting fin 16 may be made of a metal such as SUS, and one side M of the reflecting fin 16 is mirror-finished. Mirror processing is a surface treatment to reflect light, and it can be carried out by a polishing process or a white coating.

When the mirror finishing is performed on one surface of the reflecting fin 16, sunlight passing through the transmitting body is incident on one surface of the reflecting fin 16 and then reflected. The reflecting fins 16 may be inclined at a constant angle b with respect to the sea surface in order to reflect sunlight passing through the transmitting body 20 to the fresh water member and the angle may be 10 to 20 degrees with respect to the sea surface .

The reflected sunlight can be transferred to the fresh water member of the second fresh water section to be described later to increase the productivity of the fresh water. This will be described in detail later with the second fresh water section.

A black coating may be formed on the other surface of the reflecting fin 16 that is not mirror-processed. Some of the sunlight passing through the transmission body can be reflected from the sea surface. The sunlight reflected from the sea surface is transmitted to the other surface of the black coated reflection fin 16 and absorbed, Which is a heat source for heating the seawater in the storage tank 10.

In FIG. 2, mirror processing is not applied to the part immersed in the seawater, but only one side of the reflecting fin 16 located outside the seawater is mirror-processed.

On the other hand, the reflecting fin 16 is made of a material such as SUS which is easy to transmit heat, so that the heat of the fluid flowing in the flow pipe 14 can be quickly transmitted to the sea water. Therefore, it is possible to utilize waste heat such as exhaust gas flowing in the flow pipe 14 connected to the power generation facility as a heat source, to assist the heat source of seawater desalination in the season when the amount of sunshine is low, or to desalinate the seawater even at night when sunlight can not be used as a heat source So that a constant level of fresh water can be obtained at all times.

As described above, when the reflecting fin 16 according to the present invention is installed, sunlight passing through the permeable body is heated together with not only the seawater of the first fresh water section 100 but also the seawater of the second fresh water section 200 It can be used as a heat source. Thus, the productivity of the fresh water system can be increased and the efficiency can be increased.

Further, by providing the reflecting fin according to the present invention, it is possible to effectively recover the waste heat of the generator exhaust gas and use it as a heat source necessary for desalination, so that seawater can be desalinated even at night when sunlight can not be used as a heat source, , The efficiency can be increased.

The reflection fin 16 described above is installed symmetrically with respect to the flow pipe 14 so that the fluid flowing in the flow pipe 14, for example, the heat of the exhaust gas discharged from the power / electric equipment can be transmitted to the external sea water . 2, two reflection fins 16 are connected symmetrically about the flow tube 14, but if necessary, more heat is transmitted to the reflection fins 16 and the heat of the fluid flowing in the flow tube is faster in the seawater So that it can be uniformly transmitted.

The reflecting fin 16 may be integrally formed with the flow tube 14 and may be connected to the flow tube by welding. In addition, the reflecting fin 16 may be connected to the connecting member as shown in FIGS. 5 and 7 and may be formed in various shapes.

4, the reflection fin 16 may be inserted into the groove V formed on the outer surface of the flow tube 14 and connected thereto.

At this time, the reflecting fin 16 may include a protrusion so as not to be separated from the groove V, and the protrusion is engaged with the recess formed in the side wall of the groove V so that the reflection fin 16 is not separated.

As shown in Fig. 5, the reflecting fin 16 can be connected to the flow tube 14 by the connecting member 18.

The connecting member 18 is bent to enclose the flow tube 14 and both ends of the connecting member 18 are bent so as to contact the reflecting fin 16 and the bent part is coupled to the reflecting fin 16 A fastening hole is formed.

The reflective fin 16 is also provided with a fastening hole and the bolt and the nut 19 penetrating the fastening holes of the reflecting fin 16 and the connecting member 18 are used to form the flow tube 14 and the reflecting fin 16, Can be connected.

At this time, it is preferable that the connecting member 18 is installed so as to be in contact with the outer surface of the flow tube 14 or one surface of the reflecting fin 16. This is to allow the heat of the exhaust gas moving inside the flow pipe 14 to be easily transferred to the sea water through the reflecting fin 16.

6 and 7, the outer surface of the flow tube 14 may include an inclined plane S, and the inclined plane S is provided so as to be in contact with the reflective fin 16.

As shown in FIG. 1, the flow tube 14 may be a flow tube 14 having a circular cross section and an entire inner surface and an outer surface only of a curved surface. However, as shown in FIGS. 6 and 7, .

The inclined plane S is disposed in contact with the reflective fin 16 to increase the contact area between the flow tube 14 and the reflective fin 16.

When the contact area between the flow tube 14 and the reflection fin 16 increases, the heat of the fluid such as the exhaust gas of the flow tube 14 can be easily transferred to the external sea water through the reflection fin 16.

3, the flow tube 14 may include a single tube in which the fluid is introduced and discharged.

Also, as shown in FIG. 8, the flow tube 14 may be formed by connecting a plurality of small flow tubes. That is, the flow tube 14 is located in the reservoir as shown in FIG. 8, and includes a plurality of straight tubes 4 in contact with the seawater and a connecting tube 6 for connecting the adjacent straight tubes 4.

One end of the rectilinear tube 4 and the connecting tube 6 may be threaded and threaded (not shown) and may be connected to another threaded fastening tube 8.

If the flow tube 14 is formed to include the plurality of straight tubes 4 and the connection tube 6, the flow tube 14 can be easily removed, replaced, and repaired. That is, even if a portion of the flow tube 14 is damaged or corroded by an external shock or seawater, the entire flow tube 14 including the damaged or corroded portion should be replaced when the flow tube 14 is made of a single tube. However, as shown in FIG. 8, when a plurality of rectilinear tubes 4 and 6 are connected to each other, only a rectilinear tube or a connection tube in which a damaged or corroded part is located can be easily replaced.

Also, when the entire flow tube 14 is removed, it can be easily removed by removing it rather than removing it as one.

1, the water collecting tank 30 is installed on one side of the storage tank 10 in the first fresh water portion 100 and is connected to the fresh water W2 generated by heating and evaporating the sea water W1 of the storage tank 10 ) Is stored.

The sunlight is transmitted through the permeable body 20 to heat the seawater W1 of the storage tank 10 and the heated seawater evaporates in a water vapor state and forms a water droplet on the bottom surface of the permeable body 20. [ The water droplets formed on the bottom surface of the permeable body 20 flow down to the lower portion of the permeable body 20 along the bottom surface of the inclined permeable body 20 and are collected in the water collecting tank 30 located below the permeable body 20, / RTI >

Meanwhile, the second fresh water section 200 is used to desalinate the seawater by using the condensed heat of evaporated steam and the incident solar heat. The second fresh water section 200 is installed at one side of the first fresh water section 100, And includes a plurality of fresh water members (40).

Referring specifically to Figure 9, each freshwater member 40 includes a plate 43 and a wick 45.

The plate 43 is installed upright on the ground surface and a seawater supply part 47 filled with the seawater W1 is formed on the upper surface and a condensed water pocket 49 is formed on the lower surface of the plate 43 to collect the condensed fresh water W2 have.

The wick 45 is attached to the rear surface of the plate 43 and is bent at its uppermost portion to suck seawater from the seawater supply unit 47 to flow along the plate 43.

That is, the uppermost portion of the wick 45 is folded and dipped in the seawater supply portion 47 of the plate 43 so that the wick 45 absorbs the seawater of the seawater supply portion 47 with surface tension, The sea water W1 flows in the longitudinal direction of the sea water W1.

9, the wick 45 may be formed to be long along the entire length of the plate 43, and the wick 45 may be formed to contact the plate 43 at this time.

With the above-described desalination apparatus, it is possible to easily desalinate seawater by using solar heat and waste heat as heat sources.

10 is a view for explaining a process of desalinating seawater using the desalination apparatus according to the present invention.

First, the process of obtaining fresh water from the first fresh water section 100 will be described.

The seawater W1 in the storage tank 10 of the first fresh water section 100 is heated by the sunlight transmitted through the permeable body 20 and the seawater W1 evaporates and becomes steam. Thereafter, the evaporated water vapor forms a water droplet on the bottom surface of the permeable body 20, and water droplets enlarged to a predetermined size flow along the bottom surface of the inclined permeable body 20 and collect in the water collecting tank 30.

At this time, the seawater in the storage tank 10 can be heated using waste heat as well as solar heat. The waste heat can be obtained by using the exhaust gas discharged from the power generation / electric power facility of the installation area where the fresh water system of the present invention is installed. That is, the flow pipe 14 is connected to the power / electric power facility so that the exhaust gas flows inside the flow pipe. The heat of the exhaust gas is exchanged with the seawater W1 in contact with the flow pipe 14 while the exhaust gas flows through the flow pipe, so that the seawater W1 is heated and evaporated.

Thus, by using the waste heat of the exhaust gas of power generation / electric power facilities as a heat source, it is possible to assist the heat source of seawater desalination in the season when the amount of sunshine is low, or to desalinate the seawater even at night when solar energy can not be used, .

And a process of obtaining fresh water from the second fresh water section 200 will be described.

For convenience of explanation, the second fresh water section 200 including four fresh water members as shown in FIG. 10 will be described as an example. The first fresh water member 40a, the second fresh water member 40b, the third fresh water member 40c and the fourth fresh water member 40d from the fresh water member provided adjacent to the first fresh water portion 100. [ Although four fresh water members are shown in Fig. 11, it is possible to install less than four or more as necessary.

When the fresh water is produced by the first fresh water section 100, the water vapor evaporated in the first fresh water section 100 flows not only into the permeable body 20, but also to the plate of the first fresh water member adjacent to the first fresh water section 100 (40a). The diffused water vapor is contacted with the plate 40a of the first fresh water member, condensed in the form of droplets, and stored in the condensed water pocket 49a.

At this time, the latent heat of condensation generated by the condensation of water vapor is absorbed by the wick 45a and used as a heat source for heating and evaporating the flowing seawater.

That is, the seawater W1 absorbed through the wick 45, which is submerged in the seawater supply unit 47, flows along the wick 45a and is heated and evaporated by the latent heat of condensation.

In addition, the seawater flowing along the wick 45a can be heated and evaporated by the solar heat directly incident on the plate 40a through the transmission body 20, and the solar heat reflected by the reflecting fin 16, as a heat source.

That is, the sunlight passing through the transmissive member 20 is incident on the mirror-finished surface of the reflecting fin 16 and is reflected to be transmitted to the front surface of the plate 42a and used as a heat source of seawater flowing along the wick 45a have.

As described above, the seawater W1 flowing along the wick 45a can be evaporated by the latent heat of condensation, direct incident through the permeable body, and sunlight reflected by the reflecting fin 16, heated by the heat source, And condensed on the front surface of the adjacent plate 45b at the next stage and stored in the condensate water pocket 49b.

That is, when the seawater of the storage tank 10 is evaporated and then condensed on the front surface of the first plate 43a, the latent heat of condensation generated is transferred to the first wick 45a through the first plate 43a, The solar heat that is incident on the front surface of the first plate 43a through the transmitting body 20 is also absorbed by the wick 45a and the sea water flowing into the first wick 45a is heated by the wick 45a. Can be used as an additional heat source necessary for heating the heat exchanger.

At this time, the entire surface of the first plate 43a may be coated with black so as to increase the absorption rate of sunlight.

The vapor evaporated in the first wick 45a condenses on the front surface of the adjacent second plate 45b and flows down to the bottom.

The latent heat of condensation generated at the front surface of the second plate 45b is transferred to the second wick 45b through the second plate 45b and applied as a heat source for heating the seawater flowing along the second wick 45b do.

The seawater continuously heated in the second wick 45b again evaporates and condenses on the front surface of the adjacent third plate 43c. This latent heat of condensation is conducted to the heating source of the third wick 45c And is collected by the condensate pockets 49c of the third plate 43c.

As described above, the process of evaporation, condensation, conduction, evaporation, and condensation of seawater repeatedly takes place in the subsequent plates 43d, ... so as to recover the condensed water. Theoretically, The condensed water is repeatedly generated until the outside temperature reaches the outside temperature.

In the present invention, only one form of the four fresh water members 40 is shown in the present invention. However, the number of the plate 43 provided is not limited to the total amount of heat absorbed by the first plate 43a (latent heat of solar radiation and condensation) It may be reduced or increased in consideration of seawater temperature and flow rate.

In addition, the remaining seawater evaporated while flowing to the lower end through the wick 45 of the fresh water member 40 flows to the lowermost end of the wick 45 and is discharged to the outside.

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. It is to be understood that various changes and modifications may be made without departing from the scope of the appended claims.

4: Straight pipe 6: Connector
8: fastening pipe 10: storage tank
14: Flow tube 16: Reflecting fin
18: connecting member 19: bolt and nut
20: permeable body 30: water collecting tank
40: fresh water member 43: plate
45: Wick 47: Seawater supply section
49: Condensate pockets 80: Power plant
100: first fresh water part 200: second fresh water part
1000, 1002: Fresh water system

Claims (11)

A reservoir for storing seawater;
A flow pipe installed in the reservoir to be in contact with the seawater;
A reflection fin including a lower fin protruding outwardly from the flow pipe and connected directly to the flow pipe, the upper fin protruding above the water surface of the seawater and the lower fin submerged below the water surface of the seawater;
A permeable body installed on the storage tank and inclined at a predetermined angle with respect to the water surface of the seawater; And
A collecting part installed at a lower side of the permeable body and in which seawater in the storage tank is evaporated and condensed fresh water contacts with the permeable body and flows along the permeable body;
/ RTI >
Wherein the upper fin and the lower fin are formed of a plate member extending along an extending direction of the flow pipe, and are symmetrical with respect to the flow pipe,
The upper fin reflects sunlight from one side and absorbs sunlight from the other side,
Wherein the lower fin transfers the heat of the fluid flowing in the flow tube to the seawater. The method of claim 1,
And the reflection fin is formed integrally with the flow pipe. The method of claim 1,
Wherein the reflection fin is fixed to a groove formed in the surface of the flow pipe. The method of claim 1,
Wherein the reflecting fin is fixed to the flow pipe by a connecting member. 5. The method of claim 4,
Wherein the flow tube includes an inclined surface,
Wherein the reflective fin is in contact with the inclined surface. The method of claim 1,
Wherein one surface of the upper fin is mirror-finished, and the one surface is a surface on which sunlight passing through the transmitting body is incident, using solar heat and waste heat. The method of claim 1,
Wherein the other surface of the upper fin faces the sea surface of the storage tank and uses solar heat and waste heat to absorb sunlight reflected on the sea surface. 8. The method of claim 7,
And the other surface of the upper fin is coated with a black coating of solar heat and waste heat. The method of claim 1,
Wherein the flow pipe includes a plurality of linear pipes contacting with the seawater of the storage tank, and a connection pipe connecting the linear pipes and located outside the storage tank. The method of claim 1,
Further comprising a plurality of fresh water members installed adjacent to the reservoir,
Each said freshwater member
A plate to be erected upright;
A seawater supply unit located on an upper surface of the plate and filled with seawater;
A condensed water pocket positioned at a lower side of the plate and collecting condensed water; And
A wick attached to the other surface of the plate to absorb and flow seawater from the seawater supply unit;
A desalination device using solar heat and waste heat. 11. The method of claim 10,
Wherein one surface of the plate is made of solar heat and waste heat, which is a plane on which sunlight reflected from one surface of the reflective fin is incident.

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