KR20150079198A - MED having Separated Vapor Path - Google Patents

Abstract

The present invention relates to a multi-effect distillation (MED) apparatus equipped with a distribution-type steam path, and more specifically, to a multi-effect distillation apparatus equipped with a distribution-type steam path wherein a steam moving path is separated up and down of a heat transfer tube and thereby a pressure loss and a heat loss are lowered. The multi-effect distillation apparatus according to one embodiment of the present invention comprises: an inlet tube through which a seawater is supplied; a heat exchanger for generating steam by heating the seawater; an effect having a heat transfer tube through which the steam flows wherein the seawater is injected to the heat transfer tube, some of the seawater evaporates and condenses so as to form a fresh water and a brine water; a first steam path formed in an upper portion of the heat transfer tube; and a second steam path formed in a lower portion thereof for the multi-effect distillation (MED) apparatus equipped with a brine water discharge tube through which the brine water is discharged.

Description

MED having Separated Vapor Path < RTI ID = 0.0 > (MED) < / RTI &

The present invention relates to a MED having a distributed steam path, more particularly, to a MED having a dispersed steam path for reducing a pressure loss and a duct loss by discharging a steam traveling path up and down a heat transfer tube will be.

MED (Multi Effects Distillation) is a type of seawater desalination device and is sometimes referred to as multi-effect evaporation method. The evaporation method is a method of producing distilled water by condensing the evaporated water vapor by evaporating the seawater. It is mainly composed of multi stage flashing (MSF) and multi utility evaporation (MED) The evaporation method (MED) is a widely used method since it consumes less power than the multistage evaporation method (MSF).

MED The seawater desalination plant heats the seawater by receiving steam from a steam turbine or a heat recovery steam generator of a power plant and after the steam is generated from the heated seawater The distillate is obtained, and the remaining brine is returned to the sea. On the other hand, the steam generated in each stage enters the heat transfer tube of the next stage (Next Effect) and acts as a heat source.

A more detailed description will be made with reference to the operation of the MED facility shown in Fig. 1 and the operation of the MED shown in Fig.

The MED evaporator consists of several successive stages, the Effect (1). Each of the effects 1 is composed of a plurality of heat transfer tubes 2 and the pressure and temperature of the first effect 1a are the highest and then the pressure and the temperature are gradually lowered toward the next effect and the pressure and temperature of the last effect 1d Is formed at the lowest level. The seawater introduced through the feed water pipe 3 is sprayed toward the heat transfer pipe 2 from the upper part of each effect 1 to wet the surface of the heat transfer pipe 2 and flow downward by gravity.

Heated steam from the power plant flows into the heat transfer pipe 2, and the steam is cooled by the flowing seawater and condensed to form distillate (fresh water). On the other hand, seawater gets latent heat and evaporates partly. At this time, the generated steam enters the pipe of the next effect and acts as a heat source, so that the next effect also goes through the same process. In addition, seawater that has partially evaporated water vapor becomes concentrated on the floor. This process is repeated for each effect. Condensate generated at each stage is finally collected and produced as fresh water (6), and each concentration water (5) is sent back to the sea by the pump.

For a basic concept and configuration of the MED with respect to the prior art, reference can be made to European Patent EP 1781390 B1 'MSF distillate driven Desalination Process and Apparatus'.

However, there is a problem in that steam generated from seawater passes between the heat transfer tubes 2 and goes to the next effect, resulting in steam pressure loss and heat loss. This is more pronounced when the steam path is long.

Further, when the moving direction of the seawater flowing through the heat transfer pipe 2 is different from the moving direction of the steam as shown in FIG. 2, the wetting is badly formed.

On the other hand, during the process of steam movement, it moves at a high speed by the energy by the evaporation of the reduced pressure, and collides with the seawater and accompanies the mist or the droplet together. When bubbles or water droplets are contained, the movement of the vapor is interrupted and the performance of the entire evaporator is deteriorated. Therefore, a method for removing air bubbles or water droplets contained in the steam is proposed. One of them used for this purpose is Demister.

In the prior art, when the evaporated steam passes through the heat transfer tube 2 and proceeds to the next effect, the mesh type demister 7 is installed on the steam moving path to remove bubbles and water droplets. However, there is a limit that the mesh type demister 7 can not be installed horizontally.

DISCLOSURE Technical Problem The present invention has been made to solve the above-mentioned problems, and an object of the present invention is to provide a method of manufacturing a honeycomb structure, in which a mesh demister is formed in a lower portion of a heat transfer tube, a vane demister is formed in an upper portion of the heat transfer tube, And to provide a MED with a distributed steam path.

The multi-function device according to an embodiment of the present invention includes an inlet pipe provided with seawater, a heat exchanger for generating steam by heating the seawater, and a heat transfer pipe through which the steam flows, the seawater is sprayed onto the heat transfer pipe, (EN) The present invention relates to a multi-function device (MED) provided with a first steam passage formed at an upper portion of a heat transfer pipe and a lower portion formed at a lower portion of the heat transfer pipe, And a second steam passage communicating with the first steam passage.

Here, the first steam passage is provided with a vane type demister.

Further, the second steam passage is provided with a wire-mesh type demister.

Further, the vane-type demister is characterized by being formed vertically.

The wire mesh demister may be formed horizontally.

Further, the heat transfer tubes are formed such that the width of the heat transfer tubes is wider than the width of the upper and lower spaces.

And 15 to 35% of the steam generated inside the effect is transferred to the next effect through the first steam passage.

According to another aspect of the present invention, there is provided a multi-function device comprising: an evaporator to which high-pressure steam is supplied from a heat source; A heat transfer tube bundle horizontally installed inside the evaporator; A vein type demister installed in a first steam passage formed on the heat transfer tube bundle; And a mesh type demister installed in a second steam passage formed under the heat transfer tube bundle.

Here, the flow direction of the seawater supplied to the evaporator and flowing down the heat transfer tube bundle is the same as the flow direction of the steam passing through the second steam passage.

Further, the vane-type demister is characterized by being formed vertically.

The wire mesh demister may be formed horizontally.

Further, in the heat transfer tube bundle, widths of the left and right gaps between the heat transfer tubes are wider than the width of the upper and lower gaps.

And 15 to 35% of the steam generated inside the effect is transferred to the next effect through the first steam passage.

According to the MED equipped with the distributed steam path according to the embodiment of the present invention, 15 to 35% of the steam generated in the evaporator is dispersed in the first steam passage formed in the upper part, so that the reduced pressure loss And the heat loss can be reduced, thereby increasing the efficiency.

In addition, since the steam moving path can be maintained in the same direction as the flow of seawater, the wetting can be maintained excellent.

Figure 1 shows the operation principle of the MED according to the prior art.
2 is a longitudinal sectional view of a heat transfer tube bundle according to the prior art.
3 is a schematic diagram of a MED device according to an embodiment of the present invention.
Figure 4 shows the Effect of a MED device according to an embodiment of the present invention.
5 is a longitudinal sectional view of a heat transfer tube bundle according to an embodiment of the present invention.
Figure 6 shows a vapor flow diagram within the MED. (b) shows a case where a first steam passage is formed at an upper portion and a second steam passage is formed at a lower portion.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings, which are intended to illustrate the present invention in a manner that allows a person skilled in the art to easily carry out the invention. And does not mean that the technical idea and scope of the invention are limited.

The multi-effusion device according to an embodiment of the present invention includes an inlet pipe provided with seawater, a heat exchanger for generating steam by heating the seawater, and a bundle of heat transfer tubes through which steam flows, the seawater is sprayed on the bundle of heat transfer tubes, (EN) An evaporator (EN), comprising: an evaporator (EN) for evaporating and condensing water to form fresh water and domestic salt water; and a nitrification water discharge pipe for discharging the nitrification water, wherein the first vapor passage And a second steam passage formed in the second steam passage.

3 is a schematic diagram of a MED device according to an embodiment of the present invention. Fig. 4 shows one effect in Fig. 3, and Fig. 5 shows a longitudinal sectional view of a tube bundle according to an embodiment of the present invention. Figure 6 shows a vapor flow diagram within the MED. Hereinafter, the present invention will be described in detail with reference to the drawings.

A high pressure steam is supplied from an electricity generating facility or a heat source to an evaporator 10. Here, the heat source may be a steam transformer. The evaporator 10 is formed by successively connecting a plurality of effects.

Inside the effect 11, a heat transfer tube bundle 12 composed of a plurality of heat transfer tubes is placed in a horizontal state. The high-pressure steam flows into the heat transfer tube bundle 12 inside the evaporator.

Sea water is connected to each effect 11 via an inlet pipe 30. Seawater is sprayed from above the respective effects (11). The sprayed seawater flows downward while soaking the outer wall of the heat transfer tube bundle 12. The high-pressure steam flowing in the heat pipe bundle 12 is condensed to form distillate (fresh water), and the injected seawater is heated due to the latent heat (condensation heat) of the high-pressure steam and partly evaporated. The seawater evaporated through the heat transfer tube bundle (12) is concentrated and accumulated in the lower portion of the evaporator (10).

The vapor formed by the evaporation of the seawater passes to the next effect and acts as a heat source (11a → 11b → 11c → 11d). This process is repeatedly performed in each effect 11. As the pressure transitions from the first effect (11a) to the next effect, the pressure and temperature of the steam become lower and the pressure and temperature at the final effect (11d) become the lowest. The steam generated in the final effect lid is condensed outside the heat transfer tube of the heat exchanger 20 and becomes fresh water 60. [ That is, temperature exchange with seawater occurs in the heat exchanger 20. And the concentrated salt solution 50 discharged from the final effect lid is returned to the sea by the pump 41. [

A first steam passage (15) is formed on the heat transfer tube bundle (12).

A vane-type demister 16 is installed in the first steam passage 15. The vane demister 16 can be installed vertically. Therefore, a demister can be provided on the heat transfer tube bundle 12, which is difficult to form a horizontal space.

A second vapor passage (17) is formed below the heat transfer tube bundle (12).

The second steam passage 17 is provided with a wire mesh-type demister 18. The wire mesh type demister 18 can be installed horizontally.

The steam is dispersed in the first steam passage 15 and the second steam passage 17 so that the decompression phenomenon occurring when the steam moves through the heat transfer tube bundles 12 can be reduced. In other words, since the steam is divided into upper and lower parts and the steam formed in the upper layer is discharged through the vane demister 16 formed on the upper part and the steam formed in the middle lower part is discharged through the wire mesh demister 18 formed in the lower part The distance traveled through the heat transfer tube bundle 12 is reduced, so that the decompression phenomenon is reduced.

Such a phenomenon can be more effectively achieved when the heat transfer tube bundle 12 is formed long and long as shown in FIG. That is, since the direction in which the seawater introduced through the inlet pipe 30 passes through the bundle of heat transfer tubes 12 arranged vertically and the direction of the steam flowing out through the second steam passage 17 are the same, The loss can be large, and this problem can be alleviated as the steam path is dispersed. In addition, in the heat transfer tube bundle 12 for facilitating such movement, the intervals between the heat transfer tubes can be formed to be wider than the widths of the upper and lower gaps.

Figure 6 shows the vapor flow condition inside the MED. (a) shows a case where a steam passage is formed only at the bottom and a wire mesh type demister is provided. (b) shows a case where a first steam passage is formed in an upper portion and a second steam passage is formed in a lower portion, a vein type demister is provided on an upper portion, and a wire mesh type demister is provided on a lower portion.

Referring to FIG. 6, as shown in (a), steam passages are formed at the upper and lower portions as shown in (b), and steam is dispersed and discharged as compared with the case where only the lower steam passage is provided. Here, the amount of steam exiting through the upper second steam passage may be about 15 to 35% of the total steam.

In the first steam passage, the vine-type demister serves to prevent the concentrated salt mist from mixing with the fresh water. In the second steam passage, the wire mesh demister serves to prevent the concentrated salt mist from being mixed with the fresh water do.

Although the present invention has been described in connection with the above-mentioned preferred embodiments, it will be apparent to those skilled in the art that various modifications and variations can be made without departing from the spirit and scope of the invention, It is self-evident to fall within the scope of the claims.

10 Evaporator 11 Effect
12 Heat pipe bundle 15 First steam passage
16 Vane type demister 17 Second steam passage
18 Wire Mesh Type Demister 20 Heat Exchanger
30 inlet pipe 41 pump
50 concentrated salt water 60 fresh water

Claims (13)

An effect of heating the seawater to generate steam, a heat exchanger having a bundle of heat transfer tubes through which the steam flows, the seawater being sprayed on the heat transfer tube bundle to partially evaporate and concentrate to form fresh water and concentrated salt water, (EN) A multiple effect device (MED) provided with an effluent discharge pipe for discharging the nitrate solution,
And a second vapor passage formed at a lower portion of the bundle of heat transfer tubes, the first vapor passage being formed at an upper portion of the heat transfer tube bundle.
The multipurpose apparatus according to claim 1, wherein the first steam passage is provided with a vane type demister.
The multipurpose apparatus according to claim 1, wherein the second steam passage is provided with a wire-mesh type demister.
The multipurpose apparatus according to claim 2, wherein the vein-type demister is vertically formed.
The multipurpose apparatus according to claim 3, wherein the wire mesh demister is horizontally formed.
The multi-function apparatus according to claim 1, wherein widths of the left and right gaps between the heat transfer tubes in the heat transfer tube bundle are wider than widths of the upper and lower gaps.
The multipurpose device of claim 1, wherein 15-35% of the steam generated within the effect is transferred to the next effect through the first steam passage.
An evaporator to which high-pressure steam is supplied from a heat source;
A heat transfer tube bundle horizontally installed inside the evaporator;
A vein type demister installed in a first steam passage formed on the heat transfer tube bundle; And
And a mesh type demister installed in a second steam passage formed at a lower portion of the heat transfer tube bundle.
The multi-function apparatus according to claim 8, wherein the flow direction of the seawater supplied to the evaporator and flowing down the bundle of the heat transfer tubes is the same as the flow direction of the steam passing through the second steam passage.
The multipurpose apparatus according to claim 8, wherein the vane-type demister is vertically formed.
The multipurpose apparatus according to claim 8, wherein the wire mesh demister is horizontally formed.
The multi-function apparatus according to claim 8, wherein widths of left and right gaps between the heat transfer tubes in the heat transfer tube bundle are wider than widths of upper and lower gaps.
The multipurpose apparatus according to claim 8, wherein 15 to 35% of the steam generated in the effect is transferred to the next effect through the first steam passage.

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