KR100937450B1 - A seawater supplying apparatus with cooling tower for a multiple stage flashing facility - Google Patents

Abstract

The present invention relates to a seawater supply apparatus for a multi-stage evaporation desalination plant that can reduce the construction cost of the seawater supply facilities by reducing the seawater supply facilities to a minimum by reducing the amount of seawater supply even if the desalination plant is enlarged. In the multi-stage evaporation desalination equipment comprising an evaporator divided into a heat recovery portion and a heat discharge portion, a seawater inlet pipe for supplying seawater from the heat discharge portion, and a seawater discharge pipe for discharging seawater used in the heat discharge portion. ; The seawater discharged from the seawater discharge pipe is cooled by using a cooling tower, and then re-supplied to the seawater inlet pipe to reduce the amount of seawater required for the freshwater evaporator.

Multistage evaporation method, desalination plant, evaporator

Description

A seawater supplying apparatus with cooling tower for a multiple stage flashing facility}

The present invention relates to a seawater supply device for a multi-stage evaporation desalination plant, and more particularly, even if the desalination plant is enlarged, the construction cost of the seawater supply facility can be reduced by minimizing the supply of seawater according to the decrease in the amount of seawater supply. The present invention relates to a concentrated brine recovery supply device for a multi-stage evaporation desalination plant that can be saved.

In general, desalination facilities produce fresh water that can use seawater and sewage as domestic or industrial water. In general, multiple stage flash (MSF) and multiple effect distillation (MED) are mainly used. In addition, there are reverse osmosis (RO) using pressure as a membrane filtration method and a hybrid type in which two or more of the above methods are mixed.

The desalination plant by the multi-stage evaporation method comprises an evaporator composed of a plurality of stages 111 and divided into a heat recovery section and a heat recovery section, as shown in FIG. 110 is provided, the stage 111 is composed of a condenser (112), a separator (Demister) 113 and a flashing chamber (114).

In addition, on one side of the evaporator 110, a concentrated brine heater for heating the preheated circulating brine (Recycling Brine) to the operating temperature using the thermal energy of the low-pressure steam supplied through the low-pressure steam supply pipe (120a) Brine Heater (120) is provided, and the other side of the evaporator 110 is provided with a deaerator (130) for removing carbon dioxide and oxygen contained in the feed-up (Make-up) flowing into the last stage of the evaporator (130) do.

In addition, the condensate recovery pump 140 is connected to the brine heater 120 so that the condensate in the brine heater 120 can be sent to the power generation facility for reuse, and the concentrated brine circulation so that the circulating brine can circulate inside the evaporator. A pump (Brine Recirculation Pump) 150 is provided and discharges the fresh water pump 160 which sends the fresh water inside the water separator 113 condensed by the evaporator to the post-treatment process and the concentrated brine that has reached the last stage of the evaporator. The concentrated brine discharge pump 170 is provided.

A vacuum system is provided as a means for removing non-condensable gases such as carbon dioxide and air that are not condensed in the evaporator 110. The vacuum system 180 is a medium pressure steam supplied through a medium pressure steam supply pipe 181. (First ejector (Pre ejector) 182 and the second ejector 183 for ejecting (Middle pressure steam) to the internal nozzle to sharply drop the pressure is provided, the non-condensable gas sucked from the evaporator by the difference in pressure The pre condensor 184, the inter condensor 185, and the ATM condensor 186, which condense heat by condensing with cold concentrated water introduced through the seawater inlet pipe 189, The condensed water inside the AT condenser 186 is discharged to the outside through the seawater discharge pipe 187, and the non-condensable gas inside the AT condenser 186 is discharged to the atmosphere through the gas discharge pipe 188. It is configured to.

The desalination plant by the multi-stage evaporation method configured as described above flows through the condenser 112 of each heat recovery portion by the concentrated brine circulation pump 150 and flows into the concentrated brine heater 120 to supply the low pressure steam supplied from the steam supply pipe 181. It is heated by the heat of condensation of (Low Pressure Steam).

In addition, the heated circulating brine is sequentially introduced into the evaporation chamber 114 of the stage 111, which is maintained at a low pressure, and the introduced circulating brine is violently flashed due to the low pressure around the evaporation chamber. Evaporation is continued while the incoming circulating brine is cooled to a break point corresponding to the pressure of the stage, and then flows into the next stage, repeating the process as described above and gradually increasing the concentration. do.

In order to adjust the concentration of the total circulating brine to reach the final stage, a part is discharged through the Brine Blowdown Pump 170, and the steam generated inside each evaporation chamber 114 is separated from the separator 113. Al salts of salts that may be contained are removed after passing through the circulating brine flowing inside the tube of the condenser 112 (hereinafter referred to as "condensation tube bundle"), and then condensed into fresh water to condense into a fresh water pump (Distillate Pump). It is to be transferred to the after-treatment process through 160.

However, in the case of using the multi-stage evaporation desalination system configured as described above, the seawater is used as cooling water, but as the multi-stage evaporation desalination plant is rapidly enlarged, the flow rate of sea water for discharging the heat generated from the fresh water evaporator becomes too large. Since the seawater supply facilities have to be enlarged, the cost of the seawater supply facilities has been increased.

The present invention has been invented to solve the above problems, by installing a cooling tower (cooling tower) to cool the seawater discharged from the seawater discharge pipe to re-supply to the evaporator, reducing the amount of seawater required for cooling and fresh water It is characterized by providing a seawater supply apparatus using a cooling tower for the multi-stage evaporation desalination plant to minimize the construction cost of the seawater supply equipment by supplying only the make-up flow rate required for fresh water production in the evaporator.

In addition, the cooling tower also aims to maximize the operating efficiency of the evaporator by appropriately adjusting the temperature of make-up water supplied to the freshwater evaporator by appropriately adjusting the amount of air according to the cooling efficiency required by the freshwater evaporator. have.

The present invention for achieving the above object is an evaporator divided into a heat recovery portion and a heat discharging portion, a seawater inlet pipe having a supply pump in the middle and supplying concentrated salt water as sea water to the heat discharging portion, and the heat In the multi-stage evaporation desalination plant comprising a seawater discharge pipe for discharging the concentrated brine used in the discharge; Cooling means discharged from the seawater discharge pipe is characterized in that the cooling means including a seawater supply unit for re-supply to the seawater inlet pipe and receives the concentrated salt water as seawater.

The cooling means may include a cooling tower having an air discharge hole 23 through which the air is discharged, and a plurality of nozzles provided in the upper portion of the cooling tower to spray and drop concentrated brine discharged by the seawater discharge pipe. It is characterized in that it is configured to be connected to the injection pipe, and the lower portion of the cooling tower is connected to the seawater discharge pipe and the lower collecting portion for supplying the concentrated brine collected by cooling through the natural drop and the lower residue to the seawater inlet pipe.

In addition, the cooling tower is characterized in that the lower portion is wider and gradually narrower toward the upper portion so as to increase the cooling rate to increase the cooling efficiency of the air.

In addition, the sea water supply unit is provided in the middle of the cooling tower is supplied with a sea water supply pipe for supplying concentrated salt water as seawater, and a sea water supply pump is provided in the middle of the sea water supply pipe to selectively supply concentrated salt water as needed .

According to the present invention as described above, even if the desalination plant is enlarged, the seawater supply facility can be reduced to the minimum by reducing the supply amount of sea water, thereby reducing the construction cost of the seawater supply facility to the maximum, thereby reducing the construction cost of the desalination facility to the maximum. It can be effective.

In addition, the cooling tower has an effect of improving the operation efficiency of the evaporator by appropriately adjusting the temperature of the make-up water supplied to the fresh water evaporator by appropriately adjusting the amount of air according to the cooling efficiency required by the evaporator.

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

1 is an overall configuration diagram showing a concentrated brine supply apparatus for a desalination plant of the first embodiment according to the present invention.

Thus, the brine recovery and supply device for the desalination plant of the first embodiment according to the present invention, the evaporator 110 divided into a heat recovery unit 110a and a heat discharge unit (110b) and sea water in the heat discharge unit (110b) In the multi-stage evaporation desalination facility comprising a seawater inlet pipe 189 having a supply pump 189a in the middle and a seawater discharge pipe 187 for discharging the concentrated salt water used in the heat discharge unit 110b. In; Cooling means (1) comprising a seawater supply unit (3) for cooling the heated seawater discharged from the seawater discharge pipe (187) to be re-supplied to the seawater inlet pipe (189) and the seawater is supplied. .

The cooling means 1 includes a cooling tower 2 having an air discharge hole 23 through which air is discharged, and a seawater discharge pipe 187 connected to the inside of the cooling tower 2. Injection pipe 21 including a plurality of nozzles (21a) for spraying and dropping the concentrated brine discharged, and is provided to be connected to the sea water discharge pipe 187 in the lower portion of the cooling tower (2) to cool through the natural falling and the residual residue It is composed of a lower collecting unit 22 for supplying the collected concentrated brine to the seawater inlet pipe (189).

In addition, the cooling tower 2, the lower portion is wider and gradually narrower toward the upper portion so as to increase the cooling rate to increase the cooling efficiency of the air.

In addition, the seawater supply unit 3 is composed of a seawater supply pipe 31 for supplying the seawater necessary for the fresh water evaporator from the sea water, and a seawater supply pump 32 for supplying seawater to the seawater supply pipe 31.

On the other hand, Figure 2 shows another embodiment of the cooling tower constituting the present invention, the cooling tower 2 further includes a cooling unit (4) capable of forcibly lowering the temperature of the concentrated brine discharged.

That is, the cooling unit 4 is provided inside the inner wall of the cooling tower 2 to a cooling tube 41 through which the refrigerant moves, and a cooling unit 42 that circulates the refrigerant by exchanging the refrigerant in the cooling tube 41. It is composed.

Hereinafter, the operating relationship of the desalination plant supply brine supply apparatus of the first embodiment according to the present invention configured as described above are as follows.

As shown in FIG. 1, when seawater is first supplied to the evaporator 110, first, the seawater supply pump 32 of the seawater supply unit 3 is operated to fill the seawater in the lower portion of the cooling tower 2.

Then, by operating the supply pump (189a) provided in the middle of the seawater inlet pipe (189) through the process of supplying the concentrated brine filled in the cooling tower (2) to the heat discharge unit (110b) of the evaporator (110) Concentrated seawater, which is seawater, is supplied to the evaporator 110.

Next, when the concentrated brine of the cooling tower 2 is supplied to the evaporator 110 as described above, some of the concentrated brine supplied to the evaporator 110 is used, the remaining concentrated brine is the temperature rises in the sea water discharge pipe 187 Inflow).

In addition, the concentrated brine introduced into the seawater discharge pipe 187 is injected from the upper portion of the cooling tower 2 through the injection pipe 21 to be cooled down while falling to the lower portion of the cooling tower 2, and is cooled while remaining in the lower collection unit 22. .

Then, the process of supplying the heat discharge part 110b of the evaporator 110 through the seawater inlet pipe 189 is continuously performed.

Therefore, by cooling the concentrated brine discharged during the process as described above and reused through the seawater inlet pipe (189), even if the capacity of the desalination plant is increased, the amount of seawater flowing into the seawater supply unit (3) will be increased. There is no need.

That is, by recycling the concentrated brine discharged by supplying a small amount of the brine corresponding to the amount of the brine used in the evaporator 110, the construction cost of the seawater supply facilities can be reduced to a minimum.

In addition, as shown in Figure 2, by providing a separate cooling unit (4) in the cooling tower (2) has the advantage to increase the fresh water productivity to the maximum by appropriately adjusting the temperature of the discharged concentrated brine. .

In addition, the cooling tower has an effect of improving the operation efficiency of the evaporator by appropriately adjusting the amount of air discharged according to the cooling efficiency required by the evaporator to appropriately adjust the temperature of the make-up water supplied to the fresh water evaporator.

1 is an overall configuration diagram showing a concentrated brine supply apparatus for a desalination plant of a first embodiment according to the present invention.

2 is a cross-sectional view showing another embodiment of a cooling tower of the present invention.

Figure 3 is an overall configuration diagram showing a desalination plant by a conventional multi-stage evaporation method.

<Description of the symbols for the main parts of the drawings>

1: cooling means

2: cooling tower

    21: injection pipe

         21a: nozzle

    22: lower collecting part

    23: air exhaust hole

3: seawater supply unit

    31: seawater supply pipe

    32: sea water supply pump

4: cooling part

    41: cooling tube

    42: cooling device

110: evaporator

      110a: heat recovery

      110b: heat exhaust unit

187: seawater discharge pipe

189 seawater inlet pipe

      189a: supply pump

Claims (5)

An evaporator 110 divided into a heat recovery unit 110a and a heat discharge unit 110b and a seawater inflow pipe having a supply brine 189a supplied to the heat discharge unit 110b and concentrated brine as a seawater. In the multi-stage evaporation desalination facility comprising a 189, and seawater discharge pipe 187 for discharging the concentrated brine used in the heat discharge unit (110b); Cooling means (1) comprising a seawater supply unit (3) for cooling the concentrated brine discharged from the seawater discharge pipe 187 to re-supply to the seawater inlet pipe (189) and receives the concentrated brine as seawater Concentrated brine recovery supply for multi-stage evaporation desalination plant. The method of claim 1, wherein the cooling means (1) A plurality of cooling towers 2 having an air discharge hole 23 through which the air is discharged are formed in the upper portion, and a concentrated brine that is provided in the upper portion of the cooling tower 2 and connected to the seawater discharge pipe 187 to discharge the concentrated brine. The injection pipe 21 including the nozzle 21a and the concentrated salt water provided at the lower portion of the cooling tower 2 to be connected to the seawater discharge pipe 187 and collected by cooling through natural dropping and the residual residue are provided in the seawater inlet pipe 189. A concentrated brine recovery supply device for a multi-stage evaporation desalination plant, characterized in that consisting of a lower collecting portion 22 to be supplied to). The cooling tower (2) of claim 2, A concentrated brine recovery supply device for a multi-stage evaporation desalination plant, characterized in that the lower portion is wider and gradually narrower toward the upper portion so as to increase the cooling efficiency by increasing the speed of air rise. The seawater supply unit (3) according to any one of claims 1 to 3, It is composed of a seawater supply pipe (31) provided in the middle of the cooling tower to supply concentrated salt water, which is seawater, and a seawater supply pump (32) provided in the middle of the seawater supply pipe (31) to selectively supply concentrated salt water as needed. A concentrated brine recovery supply for multi-stage evaporation desalination equipment characterized in that. The method of claim 2 or 3; The cooling tower (2) further includes a cooling unit (4) capable of forcibly lowering the temperature of the discharged concentrated brine; The cooling unit 4 includes a cooling tube 41 provided inside the inner wall of the cooling tower 2 to move the refrigerant, and a cooling device 42 that circulates the refrigerant by circulating the refrigerant in the cooling tube 41. Concentrated brine recovery supply for multi-stage evaporation desalination equipment characterized in that it is.

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