JP2014205580A - Evaporation concentration apparatus for caustic soda aqueous solution - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an evaporation concentration apparatus for caustic soda aqueous solution which is compact as a whole, connects an evaporator to a gas-liquid separator while securing a droplet collection efficiency of the gas-liquid separator as high as possible and allows adjustment of a supply flow rate of a dilute aqueous solution of caustic soda to the evaporator.SOLUTION: A multiple-effect evaporation concentration apparatus for caustic soda aqueous solution includes an evaporator for heating caustic soda aqueous solution to evaporate water and a gas-liquid separator for separating the concentrated solution concentrated by heating in the evaporator from evaporated water vapor. A plate type heat exchanger is used as the evaporator. Restriction orifices are arranged between a caustic soda supply amount control valve arranged in the inlet of the evaporator and the evaporator and, at least at one site, a plurality of restriction orifices are provided.

Description

  TECHNICAL FIELD The present invention relates to a caustic soda aqueous solution concentration apparatus, and more particularly to a caustic soda evaporation system using a plate-type heat exchanger as an evaporator.

Conventionally, for evaporation and concentration of aqueous caustic soda solution, a thin film descending evaporation concentrating facility using an evaporator having a thin film descending heat exchanger and a liquid chamber has been widely used.
Thin-film evaporative concentration equipment uses a shell-and-tube heat exchanger to create a thin liquid film uniformly on the inner surface of the tube, creating a flow from the top to the bottom. By heating from the side) with steam, the liquid falling in a liquid film state in the tube is evaporated and concentrated, and the concentrated liquid is stored in the lower part of the evaporator. In the case of a multi-effect type, this is a mechanism in which these are connected in multiple stages.

However, the thin film descending heat exchanger has the following problems (1) to (5).
(1) Since it is necessary to form a uniform liquid film on the inner surface of the tube, a large tube heat transfer area is required, resulting in an increase in the size of the entire facility. In particular, high-temperature, high-concentration areas require expensive corrosion-resistant materials such as nickel. Since it is necessary to use the heat exchanger, the cost of the heat exchanger becomes high, and the cost of the frame for installing the heat exchanger becomes high.
(2) Heat exchanger In order to form a uniform thin film in all tubes, a complicated liquid dispersion mechanism is required at the top liquid supply port.
(3) It is necessary to always control the amount of supplied liquid so that the liquid film is not cut mainly due to the insufficient amount of liquid in the lower area of the heat transfer tube. In many cases, the liquid at the bottom of the evaporator is pumped. Although the amount of liquid is ensured by circulating to the top of the evaporator using a large scale, a large circulation pump is required, so that the equipment cost is high and the running cost is also high.
(4) By circulating the liquid at the bottom of the evaporator to the top of the tower with a circulation pump, the liquid composition at the top of the tower changes in a direction in which the caustic soda concentration increases, and the boiling point of the liquid at the top of the tower rises to increase the heating steam. Therefore, it is necessary to increase the size of the heat exchanger in order to cover the decrease in efficiency.
(5) Due to the large amount of liquid held in the evaporator, it takes a long time to change to operating conditions, etc., and it takes a lot of work to remove the liquid from the chamber for maintenance. become.

On the other hand, before supplying the feedstock to the evaporator, it is pre-evaporated with a flash evaporation facility, and the steam generated here is used in an evaporator with a lower temperature level to effectively use the steam. Instead of increasing the heating load of low-temperature and low-concentration evaporators, instead of increasing the heating load of high-temperature and high-concentration evaporators, the technology reduces the equipment costs by reducing the size of high-temperature and high-concentration evaporators. Has been proposed (Japanese Patent Publication No. 3-44802).
Also, control the amount of liquid supplied to the top of the evaporator, and if the amount of liquid to the top of the evaporator meets the amount necessary for heat exchange, it will not circulate and if it does not meet the necessary amount of heat A technique has been proposed in which the heating efficiency is maintained by suppressing the rise in the boiling point of the liquid at the top of the tower as much as possible by switching to circulation (Japanese Patent Publication No. 6-73601).

  However, even with these improved techniques, the shell and tube type heat exchanger is used for the thin film descending evaporator, and thus the above-mentioned problems are not completely solved.

Japanese Patent Publication No. 3-44802 Japanese Examined Patent Publication No. 6-73601

  In view of the above situation, the present invention is such that the entire evaporation and concentration equipment is compact, and the evaporator and the gas-liquid separator are efficiently connected while ensuring the highest droplet collection efficiency in the gas-liquid separator. It is another object of the present invention to provide an evaporation and concentration facility for an aqueous caustic soda solution, and further to provide an evaporation and concentration device capable of adjusting a flow rate of a dilute caustic soda solution to an evaporator.

  As a result of intensive studies to solve the above-mentioned problems, the present inventor uses a plate-type heat exchanger in which a large number of heat transfer plates are stacked in an evaporator, so that an aqueous caustic soda solution flows upward in the evaporator. Therefore, in the multi-effect concentration facility for caustic soda aqueous solution that is compact in size and exhibits excellent droplet collection efficiency, the caustic soda aqueous solution supply control valve and the evaporator provided at the evaporator inlet We have completed a multi-effect concentration facility for caustic soda aqueous solution with a restriction orifice in between, and a plurality of restriction orifices in at least one of them.

  That is, the invention according to claim 1 of the present application includes an evaporator that heats an aqueous caustic soda solution to evaporate water, and a gas-liquid separator that separates a concentrated solution heated and concentrated in the evaporator and an evaporated water vapor. In the caustic soda aqueous solution concentration equipment, a plate-type heat exchanger is used for the evaporator, and a restriction orifice is installed between the caustic soda aqueous solution supply control valve and the evaporator at the evaporator inlet, and at least one of these restriction orifices Is a multi-effect concentration facility for a plurality of aqueous caustic soda solutions.

  According to a second aspect of the present invention, there is provided a restriction orifice between a caustic soda supply amount adjusting valve provided at an inlet of an evaporator and an evaporator, and at least two of the restriction orifices are provided. This is a multi-effect evaporation and concentration facility for aqueous solutions.

  The invention according to claim 3 is the multi-effect evaporative concentration apparatus for caustic soda aqueous solution according to claim 1 or 2, wherein the gas-liquid separator is a cyclone type gas-liquid separator.

  According to a fourth aspect of the present invention, the rectangular flange attached to the square nozzle at the outlet of the plate heat exchanger is connected to the gas-liquid separator through a round pipe. Item 4. A multi-effect evaporation and concentration facility for an aqueous caustic soda solution according to Item 3.

  The caustic soda aqueous solution multi-effect evaporative concentration equipment of the present invention has high thermal efficiency at the heat transfer surface, so the evaporative concentration equipment can be miniaturized, and the caustic soda aqueous solution can be efficiently concentrated. By installing a restriction orifice and switching the operation, it is easy to adjust the flow rate of the dilute caustic soda solution to the evaporator.

It is the schematic of the multi-effect evaporative concentration equipment of the caustic soda aqueous solution which used the plate type heat exchanger for the evaporator. FIG. 3 is a partial view of a multi-effect evaporative concentration facility for an aqueous caustic soda solution in which two restriction orifices are installed between a caustic soda supply control valve and an evaporator. It is the schematic of the connection part of an evaporator (plate type heat exchanger) and a cyclone type gas-liquid separator. It is the schematic of the connection pipe of an evaporator and a gas-liquid separator. It is the schematic of the inlet nozzle attachment part to a cyclone type gas-liquid separator straight body.

The multi-effect evaporative concentration equipment of the caustic soda aqueous solution in the present invention uses a plate-type heat exchanger in which a large number of heat transfer plates are stacked as an evaporator, and at the outlet side of the evaporator, vapor generated by evaporation of dilute caustic soda aqueous solution and Since the concentrated caustic soda aqueous solution is discharged as a mixture, a gas-liquid separator for separating the evaporated vapor and the concentrated caustic soda aqueous solution is installed.
The aqueous caustic soda solution used for evaporation and concentration is not particularly limited, and examples thereof include an aqueous caustic soda solution having a concentration of about 32% by mass obtained by an electrolytic reaction of sodium chloride.

  The present invention will be described in more detail with reference to the accompanying drawings.

FIG. 1 shows an outline of a multi-effect evaporation / concentration facility for an aqueous caustic soda solution according to the present invention. In FIG. 1, 1A, 1B and 1C denote plate heat exchangers (evaporators), 2A, 2B and 2C denote gas-liquid separators, 3A, 3B and 3C denote plate-type heat exchangers and gas-liquid separators. The connecting pipe to be connected is shown.
For example, the diluted caustic soda aqueous solution (32% by mass) to be concentrated is supplied to the inlet at the lower side of the evaporator 1C and flows upward in the evaporator 1C. On the other hand, the vapor from the gas-liquid separator 2B is supplied to the inlet at the upper side of the evaporator 1C and flows downward in the evaporator 1C. The dilute caustic soda aqueous solution is heated in the evaporator 1C by the vapor from the gas-liquid separator 2B, discharged from the outlet at the upper side of the evaporator 1C as a mixture of the evaporated vapor and the concentrated caustic soda aqueous solution, and then passed through the connecting pipe 3C. It enters the straight body of the liquid separator 2C. On the other hand, the vapor from the gas-liquid separator 2B is condensed by being used for heating in the evaporator 1C, and is discharged as a drain from the outlet at the lower side of the evaporator 1C.

  The vaporized vapor and the concentrated caustic soda aqueous solution are separated in the gas-liquid separator 2C, and the concentrated caustic soda aqueous solution is extracted from the bottom of the gas-liquid separator 2C by the liquid feed pump 4C, and the inlet located at the lower side of the next evaporator 1B. To be supplied. On the other hand, the evaporated vapor separated by the gas-liquid separator 2C is discharged from the top of the gas-liquid separator 2C, then condensed by the condenser 5, and the non-condensate is exhausted by the vacuum generator 6.

  The aqueous caustic soda solution supplied to the inlet at the lower side of the evaporator 1B flows upward in the evaporator 1B. On the other hand, the vapor from the gas-liquid separator 2A is supplied to the inlet at the upper side of the evaporator 1B and flows downward in the evaporator 1B. The aqueous caustic soda solution is heated by the vapor from the gas-liquid separator 2A in the evaporator 1B, discharged from the outlet at the upper side of the evaporator 1B as a mixture of the evaporated vapor and the concentrated caustic soda aqueous solution, and then passed through the connecting pipe 3B. The straight body part of the separator 2B is entered. On the other hand, the vapor from the gas-liquid separator 2A is condensed by being used for heating in the evaporator 1B, and is discharged as a drain from the outlet at the lower side of the evaporator 1B.

  In the gas-liquid separator 2B, the vaporized vapor and the concentrated caustic soda aqueous solution are separated, and the concentrated caustic soda aqueous solution is extracted from the bottom of the gas-liquid separator 2B by the liquid feed pump 4B, and the inlet at the lower side of the next evaporator 1A. To be supplied. On the other hand, the evaporated vapor separated by the gas-liquid separator 2B is discharged from the top of the gas-liquid separator 2B, and then enters the evaporator 1C and is used as heating steam.

  The aqueous caustic soda solution supplied to the inlet at the lower side of the evaporator 1A flows upward in the evaporator 1A. On the other hand, the heating steam is supplied to the inlet at the upper side of the evaporator 1A and flows downward in the evaporator 1A. The aqueous caustic soda solution is heated by the heating steam in the evaporator 1A, discharged from the outlet at the upper side of the evaporator 1A as a mixture of the evaporated vapor and concentrated caustic soda aqueous solution, passed through the connecting pipe 3A and directly connected to the gas-liquid separator 2A. Enter the torso. On the other hand, the steam for heating is condensed by being used for heating in the evaporator 1A, and is discharged as a drain from the outlet at the lower side of the evaporator 1A.

  In the gas-liquid separator 2A, the vaporized vapor and the concentrated caustic soda aqueous solution are separated, and the concentrated caustic soda aqueous solution is extracted as a product from the bottom of the gas-liquid separator 2A by the liquid feed pump 4A (the concentration is 48% by mass in FIG. 1). . On the other hand, the evaporated vapor separated by the gas-liquid separator 2A is discharged from the top of the gas-liquid separator 2A, and then enters the evaporator 1B to be used as heating steam.

  The product caustic soda aqueous solution extracted from the bottom of the gas-liquid separator 2A and the heated steam drain discharged from the lower side of the evaporator 1A have a high temperature level. Therefore, in order to recover this thermal energy and use it effectively, The aqueous caustic soda solution extracted from the liquid separator 2C and supplied to the evaporator 1B, and the aqueous caustic soda solution extracted from the gas-liquid separator 2B and supplied to the evaporator 1A are used as the high-temperature product aqueous caustic soda solution described above. In addition, a preheater for recovering heat energy by exchanging heat with the drain of the heating steam may be provided (the preheater is omitted in FIG. 1).

FIG. 2 shows a partial view of a multi-effect evaporative concentration apparatus for caustic soda aqueous solution in which two restriction orifices are provided between the caustic soda aqueous solution supply amount control valve and the evaporator in the present invention.
In FIG. 2, 1 is a plate-type heat exchanger (evaporator), 2 is a gas-liquid separator, 3 is a connecting pipe connecting the evaporator and the gas-liquid separator, 7 is a caustic soda aqueous solution supply control valve, 8-1 8-2 are restriction orifice switching valves, and 9-1 and 9-2 are restriction orifices.

When supplying dilute caustic soda solution to the evaporator in a multi-effect evaporative concentration facility, the supply flow rate is adjusted with the caustic soda solution supply control valve provided at the inlet of the evaporator, but the liquid temperature of the dilute caustic soda solution supplied is the pressure. When the boiling point of the liquid is exceeded, a part of the liquid evaporates in the supply pipe, and the supply flow rate cannot be accurately adjusted.
On the other hand, a restriction orifice is installed between the supply amount control valve and the evaporator, and the restriction orifice has a liquid flow resistance, thereby increasing the pressure in the pipe upstream of this and raising the boiling point of the liquid. As a result, it is possible to prevent the liquid from evaporating in the pipe and to accurately adjust the supply amount.

  However, when the multi-effect evaporative concentration equipment is operated at a lower rated capacity for production adjustment or the like, it is necessary to reduce the flow rate of the diluted caustic soda aqueous solution supplied to the evaporator accordingly. The flow resistance at the restriction orifice described above varies depending on the amount of liquid flow. If there is a large amount of liquid passing through the restriction orifice, the liquid flow resistance increases, and if the liquid volume is small, the flow resistance decreases. As the pressure decreases, the pressure in the pipe upstream of the restriction orifice also decreases.

In this case, with the orifice restriction orifice designed based on the rated capacity, the flow resistance at the orifice is small when the operating load is low, so the pressure in the upstream pipe does not rise sufficiently and the liquid evaporates in the pipe. It can happen.
In order to prevent evaporation of the liquid in the piping even if the operating load is reduced from the rated capacity, a plurality of limiting orifices with different orifice diameters are prepared in parallel, and a switching valve for the limiting orifice is set according to the operating load. By switching and using, it becomes possible to cope with it (in FIG. 2, the two limiting orifices 9-1 and 9-2 are switched to operate).
In addition, it becomes possible to cope with an operating load of 25% to 100% by selecting the restricted orifice diameter.

  The gas-liquid separator in the multi-effect evaporative concentration equipment of the caustic soda aqueous solution of the present invention is a cyclone type that performs separation using centrifugal force of a swirling flow, a mesh demister type that is equipped with a mechanism for physically capturing droplets, etc. Any type can be used, but the cyclone type gas-liquid separator has advantages such as simple structure, high droplet collection efficiency and low pressure loss during operation. The gas-liquid separator is preferred.

  In general, cyclone type gas-liquid separators often have a rectangular cross-sectional shape of the inlet nozzle for the purpose of obtaining a good swirl flow in order to maintain high droplet collection efficiency, and are also commercially available for evaporator applications. Some plate-type heat exchangers have a rectangular shape or a shape close to the outlet nozzle on the premise of connection with a cyclone type gas-liquid separator.

  In the multi-effect evaporative concentration equipment, if the concentration of the aqueous caustic soda solution is increased through each evaporator, the operating temperature increases accordingly, so high-temperature and high-concentration evaporators (heat exchangers and gas-liquid separators) Due to internal liquid temperature and pressure, in Japan, it may fall under the pressure vessel (type 1 pressure vessel) defined by the Industrial Safety and Health Act. The same applies to the case where a plate heat exchanger is used, and the plate heat exchanger and the gas-liquid separator connected to the plate heat exchanger may correspond to pressure vessels (first type pressure vessels).

  When applicable to a pressure vessel, as the cross-sectional shape of the connection nozzle to be attached to the vessel, the law (pressure vessel structure standard) does not specify a rectangular nozzle, so the nozzle shape must be round, but as described above In addition, the cross-sectional shape of the outlet nozzle of the plate-type heat exchanger itself marketed for evaporator applications is rectangular or close to this, and the cyclone-type gas-liquid separator connected to this has also been captured. In view of collection efficiency, the inlet nozzle generally has a rectangular cross-sectional shape.

  For this reason, when a plate-type heat exchanger is used as an evaporator and a cyclone-type gas-liquid separator is installed in the evaporator, and these fall under pressure vessels, It is necessary to solve the problem of connecting the evaporator and the gas-liquid separator while ensuring the highest droplet collection efficiency in the gas-liquid separator without impairing the advantages of the mold heat exchanger.

  In order to satisfy the pressure vessel structure standard, it is necessary to convert the rectangular nozzle of the plate type heat exchanger or the outlet nozzle after that into a round type nozzle and connect the cyclone type gas-liquid separator inlet nozzle as a round type. is there. Originally, the plate heat exchanger to cyclone gas-liquid separator that should be manufactured with a rectangular nozzle must be changed to a round shape due to legal restrictions. However, it is important not to impair the advantages of the plate heat exchanger and to reduce the efficiency of the cyclone gas-liquid separator as much as possible.

  3 and 4 show connection pipes between the plate heat exchanger and the gas-liquid separator. The connecting pipe is a rectangular flange attached to the square nozzle at the outlet of the evaporator, a round pipe connected to this, and a gas-liquid separator attached to the end of the round pipe opposite to the rectangular flange. It is preferably constructed from a round flange.

  The size of the round pipe at which position of the rectangular flange is important, and the effective cross-sectional area at the outlet of the evaporator is used so as not to disturb the flow of the evaporated vapor and concentrated caustic soda solution as much as possible. Therefore, it is desirable that the diameter of the round pipe is as large as possible, and the amount of liquid retained in the evaporator can be reduced if the vertical position of the round pipe is as low as possible. Therefore, it is desirable in that the advantage of the plate-type heat exchanger that the amount of liquid retained is small.

  Specifically, when the flange that attaches the round pipe is a vertically long rectangle, the length of the short side (horizontal direction) of the portion excluding the mounting allowance for the plate heat exchanger is a, and the long side (vertical) (Direction) is b, and the outer diameter of the round pipe at the gas-liquid separator inlet is d. Desirably, d = a, and the lower end of the pipe is placed in contact with the lower end of the rectangle excluding the mounting allowance. Is the case.

  In practice, standard size products are often used for pipes, and the value of d cannot be chosen arbitrarily. Joining costs are also required when joining rectangular flanges and round pipes. Plate heat exchangers In view of various restrictions such as that the outlet of the pipe may not be a perfect rectangle, the size of the pipe diameter d is preferably in the range of 0.58a to a.

  Furthermore, instead of converting from the rectangular flange attached to the plate heat exchanger to the round pipe diameter d at a time, the intermediate diameter d 'is passed through, such as rectangular flange → pipe diameter d' → pipe diameter d. Finally, the pipe diameter d may be reduced. In this case, it is desirable to use an eccentric reducer between the pipe diameters d ′ to d, and connect the pipe lower ends together.

  FIG. 5 shows the inlet nozzle mounting portion to the cylinder of the cyclone type gas-liquid separator. In a general cyclone type gas-liquid separator, the size of the inlet nozzle is D with respect to the inner diameter D of the cylinder body. / 2, with a rectangle of D / 5 on the side. When this rectangular shape is round, the droplet collection efficiency is lowered, but the rectangular nozzle is not permitted by law, so it is replaced with a round pipe.

  Assuming that the rectangular nozzle is replaced with a round pipe having the same cross-sectional area in order to prevent the flow of steam and caustic soda aqueous solution as much as possible, the radius d of the round pipe is expressed as 0.357D. From this, D = 2.80d, and the diameter of the cyclone is obtained from the diameter of the connected round pipe. However, the diameter of the cyclone calculated from the diameter of the round pipe is not limited to this, and although there is no problem with some excess or deficiency, if the cyclone diameter is reduced, the pressure loss increases due to the characteristics of the cyclone and can be processed The amount is reduced, and it is not desirable from the viewpoint of equipment cost to increase the cyclone diameter unnecessarily. For this reason, it is preferable that the diameter D of a cyclone is 2.6d-4.0d, More preferably, it is 2.8d-3.5d.

  When attaching a round pipe nozzle to this cyclone, it is desirable that the outer pipe edge of the nozzle overlap the tangent of the cyclone straight body part in order to make the swirl flow inside the cyclone as good as possible. In particular, there are restrictions on the production of the container, so it cannot be produced so as to overlap the tangent of the straight body.

  On the other hand, even if the position of the inlet nozzle is too close to the center line of the cyclone straight body portion, the effect of collecting the droplets by the cyclone is reduced. Therefore, the desired inlet nozzle position is the cyclone of the inlet nozzle of the cyclone type gas-liquid separator. When the deviation from the centerline of the straight cylinder of the gas-liquid separator is x and the radius of the cylinder of the cyclone-type gas-liquid separator is r, the distance from the centerline of the cylinder of the cyclone gas-liquid separator is The deviation rate (x / r) of the inlet nozzle is preferably 0.500 to 0.642, more preferably 0.540 to 0.642.

Based on the above concept, by connecting pipes and cyclone type gas-liquid separators, it is possible to connect plate type heat exchangers and cyclone type gas-liquid separators while complying with laws and regulations related to pressure vessels. At the same time, it is possible to maintain good separation efficiency in the cyclone type gas-liquid separator.
The connection pipe is not limited to the cyclone type as a gas-liquid separator type, and generally has a round inlet nozzle and the nozzle mounting position is eccentric from the center line, such as a mesh demister type. It can be applied to those that do not.

  By using the multi-effect evaporative concentration equipment of the caustic soda aqueous solution of the present invention, for example, a 32 mass% caustic soda aqueous solution obtained by an electrolytic reaction of sodium chloride can be concentrated to obtain a 48 mass% caustic soda aqueous solution.

The caustic soda aqueous solution multi-effect evaporative concentration equipment of the present invention has excellent separation efficiency in the gas-liquid separator, and has high heat efficiency on the heat transfer surface, and the entire equipment becomes compact. It can be widely used for evaporation and concentration.
The multi-effect evaporative concentration equipment of the present invention is not limited to a caustic soda aqueous solution, but is an equipment applicable to the evaporation and concentration of various aqueous solutions such as a caustic potash aqueous solution.

1A, 1B, 1C Evaporator (plate type heat exchanger)
2A, 2B, 2C Gas-liquid separators 3A, 3B, 3C Connecting pipes 4A, 4B, 4C for the evaporator and gas-liquid separator Liquid feed pump 5 Condenser 6 Vacuum generator 7A, 7B, 7C Caustic soda aqueous solution supply flow rate control valve 8A Restriction orifice switching valve 9A, 9B, 9C Restriction orifice 1-1 Evaporated steam and concentrated caustic soda aqueous solution outlet (rectangular)
1-2 Heated steam drain outlet 1-3 Heated steam inlet 1-4 Dilute caustic soda aqueous solution inlet 2-1 Evaporated steam and concentrated caustic soda aqueous solution inlet nozzle (round)
2-2 Steam outlet 2-3 Concentrated caustic soda aqueous solution outlet 3-1 Rectangular flange outer frame and shaded part are attached to the plate type heat exchanger 3-2 The rectangular flange is attached to the plate type heat exchanger. Excluded part 3-3 Round pipe 3-4 Round flange for gas-liquid separator connection 2-1-1 Gas-liquid separator inlet nozzle (round pipe)
2-1-2 Inlet nozzle flange (round)
x Deviation of the inlet nozzle from the center of the gas-liquid separator r Cyclone-type gas-liquid separator straight body radius (D / 2)

Claims (4)

  A plate-type heat exchanger in a caustic soda aqueous solution evaporating and concentrating facility comprising an evaporator that evaporates water by heating an aqueous caustic soda solution, and a gas-liquid separator that separates evaporated liquid vapor and evaporated water vapor in the evaporator Is used in the evaporator, and a restriction orifice is installed between the caustic soda aqueous solution supply control valve and the evaporator at the evaporator inlet, and at least one of the restriction orifices is a multiple effect evaporation concentration of caustic soda aqueous solution. Facility.   The multi-effect evaporative concentration equipment of caustic soda aqueous solution according to claim 1, wherein a restriction orifice is installed between the caustic aqueous solution supply amount control valve provided at the inlet of the evaporator and the evaporator, and at least one of the restriction orifices is installed. .   3. The multi-effect evaporation / concentration facility for aqueous caustic soda solution according to claim 1 or 2, wherein the gas-liquid separator is a cyclone type gas-liquid separator.   The rectangular flange attached to the square nozzle at the outlet of the plate heat exchanger and the gas-liquid separator are connected via a round pipe. Multi-effect evaporative concentration equipment for aqueous caustic soda.

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