DE2160994A1 - Cooling crystallizer - Google Patents

Description

Escher Wyss Aktiengesellschaft, Zurich / Switzerland

Cooling crystallizer

The invention relates to a cooling crystallizer with a prism-like container, with a cooler arranged in this container with tubes as heat exchange elements, which Pipes are flushed on their inner wall by a coolant and on their outer wall by a solution to be cooled, wherein the container a device for the controllable supply and discharge of the solution, and the cooler a device for the controllable Supply and discharge of the coolant is assigned, and at least one agitator with propeller to circulate the solution is used.

Such cooling crystallizers are used for crystallization by cooling various saturated solutions, such as e.g. for the precipitation of sodium chloride from one derived from diaphragm electrolysis Sodium hydroxide solution after previous concentration to 50 # NaOH, or for the precipitation of sodium sulfate from an enriched sodium chloride brine and further to the precipitation of other products from solutions with the The above solutions have similar temperature-dependent solubility ratios.

There were also other constructions than the one mentioned at the beginning - Executed for the above-mentioned purpose, e.g. with rotary-shaped containers, or those with a Coolant, mostly cooling water, the outer wall of the pipes of the Pt. V 47

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The cooler is flushed and the solution to be cooled is passed through the pipes.

The aforementioned relatively viscous solutions tend to form incrustations when they are treated in the previous cooling crystallizers on both sides of the walls of the pipes. Because of the laminar flow conditions, the heat transfer conditions are confusing and therefore the conditions for cooling the solution are difficult to choose and set. With the inaccessibility The incrustations that occur on both sides of the walls of the pipes can only be removed with difficulty or at all do not remove. The efficiency of the system decreases gradually, if not because of complete encrustation, mostly the side of the solution, the system has to be taken out of operation.

The inventor has therefore set himself the task through improved Arrangement of the individual elements of the cooling crystallizer to achieve a continuous crystallization process that is as trouble-free as possible.

This goal is achieved with the cooling crystallizer mentioned at the beginning achieved according to the invention in that two opposing walls of the prism-like container as tube plates for straight pipes of the cooler that are parallel to one another and are guided through the container, the pipes are essentially transverse to a circulating flow direction of the solution exerted by the agitator.

A particularly turbulent flow of the solution on the pipes of the cooler is achieved by the fact that the space of the cooler with its tube plates and tubes has a passage cross-section of an elongated rectangle whose width is at most

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one third of its length. Overlookable heat transfer processes are achieved in that the tubes are arranged in tiers with respect to the path of the coolant through the cooler are connected in parallel on the floors, but the floors are connected in series, and that in the container, in addition to the space of the cooler, two additional spaces are left free, which on the one hand are connected to one another only over the space of the cooler on the other hand by means of an outside the bypass lying on the container are connected, in which bypass the propeller of the agitator is arranged, wherein the solution to be cooled flows essentially in countercurrent to the coolant.

It is advantageous if part of the cooling is carried out by adding the freshly supplied solution to the already cooled and im Container overturned solution takes place. This is achieved by that the liquid content of the adjoining room, which in the sense of the circulating flow of the solution, the room of the cooler follows, is at least as large as the liquid content of the solution in the cooler, the device for feeding dei Solution flows into the diversion and the device for discharging the solution at a higher point than the feed, is arranged in particular at the highest point of the container, and further in that the device for feeding the Solution opens into the diversion at a point which is in the sense of the circulating flow of the solution in front of the propeller the agitator is located.

The accessibility of the pipes for possible cleaning of incrustations this ensures that the tube plates together with the tubes from the cooling crystallizer in the longitudinal direction of the pipes are extendable, or that at least one

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Wall of the cooler is provided with a coverable window hole for cleaning the outer wall of the pipes, and further, that the two tube plates are provided on their outside with removable end covers, whereby the inner wall of the Pipes accessible for cleaning.

In some cases it is advantageous if the straight and to each other parallel pipes of the cooler are led through the pipe plates at an angle of up to 10 °.

If the diversion lies between two levels, which through the two bounding the container to the axes of the pipes of the cooler parallel walls are determined, can be made from the inventive cooling crystallizers as modular units assemble a crystal solution «in which the available space is due to the prism-like shape the modular units are well utilized.

Due to the various possible combinations when putting together such a cooling crystallization system the necessary physical conditions of the given crystal " can be achieved precisely with the applied As a modular principle, individual parts can be replaced in the event of degenerate malfunctions without losing a great deal of time.

The invention is described and explained in more detail below with reference to the accompanying drawing:

Fig. 1 shows a longitudinal section through a cooling crystallizer

after a first run,
2 shows a side view of the cooling crystallizer

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in Pig. 1 from the direction of the arrow pointing to FIG. 1,

Fig. 3 shows another embodiment in longitudinal section and 4 shows a longitudinal section through the cooler of a cooling crystallizer with inclined tubes.

The cooling crystallizer according to the first embodiment has a prism-like container 1 with a cooler 2 arranged in this container 1 with tubes 3 as heat exchange elements. The tubes 3 are rinsed on their inner wall by a coolant and on their outer wall by a solution to be cooled. A device for the controllable supply and discharge of the solution (the device is not shown) is assigned to the container 1 and is connected to the solution inlet nozzle 4 or solution outlet nozzle 5. A device (not shown) for the controllable supply and discharge of the coolant is also associated with the container 1, which device is connected to the coolant inlet connector 6 or coolant outlet connector 7 . An agitator 8 with a propeller 9 is used to circulate the solution in the container 1. Two opposing walls 10 and Ii of the prism-like container 1 are designed as tube plates for straight, parallel tubes 3 guided through the container i. The tubes 3 are essentially transverse to a circulating flow direction exerted by the agitator 8 or the propeller 9 (arrows in Fig.l) of the solution.

The space of the cooler 2, which is delimited by the walls 10 and Ii designed as tube plates and further by the side walls 12 and 13 and through which the tubes 3 are guided, has a passage cross-section of an elongated rectangle, the width B of which is at most a third of its Length L is. The tubes 3 are through with respect to the path of the coolant

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the cooler 2 arranged so that it is in the horizontal direction are connected in floors (in the longitudinal section, the individual floor can only be seen as a tube 3). These are the floors individual tubes 3 connected in parallel with one another. The floors, however, are connected in series one behind the other. In the container 1, two adjoining rooms 15 and 15 are left free in addition to the space of the cooler 2. These side rooms 14 and 15 are with each other on the one hand only connected via the space of the cooler 2, while on the other hand by means of an outside of the container 1 lying diversion 16 are connected. The propeller 9 of the agitator is arranged in this diversion i6. the The solution to be cooled moves essentially in countercurrent to the coolant flowing through the nozzle 6 into the tubes 3 of the cooler 2 enters and is discharged from this through connection 7. The liquid content of the adjoining room 14, which in the In the sense of the circulating flow of the solution following the space of the cooler 2, it is at least as large as the liquid content the solution in the space of the cooler 2. The device for supplying the solution (not shown) opens into the bypass 16 the nozzle 4. The device for discharging the solution (not shown) is connected to the nozzle 5, that is to say on a point that is higher than the nozzle 4, in this case at the highest point of the container 1. The device for Feeding the solution (not shown) opens through the nozzle into the bypass 16 at the point that is in the sense of Circulating flow of the solution is located in front of the propeller 9. The cooler 2 with the walls 10 and 11 designed as tube plates Is formed as a unit together with the tubes 3 and can be pulled out as a whole from the container 1 in the longitudinal direction of the tubes 3, (not drawn)

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Because of the accessibility of the outer walls of the tubes 3 is Side wall 12 of the container i can be folded down. For the same purpose, at least one side of the cooler 2, i.e. provided in the wall 12 and / or 13 coverable window holes will.

Because of the accessibility of the inner walls of the tubes 3 are the two walls designed as tube plates IO and 11 with removable Front covers 17 and 18 provided.

The cooling crystallizer in Fig. 3 differs from that just described only by the fact that the whole construction is turned by 90. The solution inlet nozzle is with 19 designated. The solution outlet nozzle with 20. The coolant inlet nozzle is designated with 21, the coolant outlet nozzle with 22. The agitator propeller 1st with 23 designated. In this cooling crystallizer, too, the solution to be cooled flows essentially in countercurrent to the coolant.

In the embodiment of the cooler shown in FIG. 4, the opposing walls 24 and 25 are designed as tube plates for the straight tubes 26 that are parallel to one another. The tubes 26 are guided through the tube plates 2 ¹ J and 25 at an angle to 10. The bypass 16 lies between two planes which are defined by the two walls 12 and 13 of the container 1. These walls 12 and 13 delimit laterally the container 1 and run parallel to the longitudinal axes of the tubes of the cooler 2. The diversion 16 can therefore not be seen in FIG.

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Claims (10)

Claims 1. Cooling crystallizer with a prism-like container, with a cooler arranged in this container with tubes as heat exchange elements, which tubes on their inner wall are flushed by a coolant and on their outer wall by a solution to be cooled, the container a device for the controllable supply and discharge of the solution and the cooler a device for the controllable Supply and discharge of the coolant is assigned and at least one agitator to circulate the solution is used with a propeller, characterized in that that two opposing walls (10, 11) of the prism-like container (1) as tube plates designed for straight pipes (3) of the cooler (2) which are parallel to one another and run through the container (1) are, wherein the tubes (3) are essentially transverse to a circulation flow direction exerted by the agitator (8) the solution. 2. Cooling crystallizer according to claim 1, characterized in that that the space of the cooler (2) with its tube plates (10, 11) and tubes (3) has a passage cross-section of an elongated rectangle, the width (B) of which is at most a third of its length (L) is. 3. Cooling crystallizer according to claim 2, characterized in that that the tubes (3) are arranged in floors with respect to the path of the coolant through the cooler (2) are connected in parallel with each other on the floors, but the floors are connected in series 209829/0872 -9- are, and that in the container (1) in addition to the space of the ' cooler (2) two adjoining rooms (14, 15) are left free, which on the one hand only over the space of the cooler (2) on the other hand by means of an outside of the container (1 ) lying bypass (16) are connected, in which bypass (16) the propeller (9) of the agitator (8) is arranged, the solution to be cooled flowing essentially in countercurrent to the coolant. 4. Kuhlkristallizer according to claim 3, characterized in that the liquid content of the adjoining space (14) which follows the space of the cooler (2) in the sense of the circulating flow of the solution, is at least as large as the liquid content of the solution in the cooler (2), wherein the device for feeding the solution opens into the bypass (16) and the device for discharging the solution is arranged at a higher point (5) than the feed, in particular at the highest point of the container (1). 5 cooling crystallizer according to claim 4, characterized in that that the device for feeding the solution into the diversion at one point (4) opens, which is in the sense of the circulating flow of the solution in front of the propeller (9) of the agitator (8). 6. Cool crystallizer according to claim 1, characterized in that that the tube plates (10, 11) together with the tubes (3) from the cooling crystallizer can be pulled out in the longitudinal direction of the tubes (j5). -10-209829 / 0872 7 cooling crystallizer according to claim 1, characterized in that that at least one wall (12 or 13) of the cooler (2) with a coverable window hole is provided for cleaning the outer wall of the pipes. 8. Cooling crystallizer according to claim 1, characterized in that that the two tube plates (10, 11) have removable end covers (17, l8) are provided, whereby the inner wall of the pipes is accessible for cleaning. 9 cooling crystallizer according to claim 1, characterized in that that the straight and mutually parallel tubes (26 in Fig. 4) of the cooler around a Angle up to 10 ° diagonally through the tube plates (24, 25 in Fig. 4 are led. 10. Cooling crystallizer according to claim 3, characterized in that that the diversion (l6) lies between two levels, which through the two the container (1) limiting to the axes of the tubes (3) of the cooler (2) parallel walls (12 and 13) of the container (1) determined are. 209829/0872 ORIGINAL INSPECTEd