NL1005540C2 - Condensing water from contaminating process - Google Patents

Abstract

A water-containing liquid is sublimed or condensed in a closed space containing separated vertical and mainly parallel tubes. These are cooled internally with a coolant. The liquid is supplied through an inlet to the space, which connects to a vat for the liquid. Also claimed is an apparatus for carrying out the method described above consisting of a jacket containing condensing tubes with a supply of coolant to the tube tops and drainage from their bases and a supply of the liquid. The tops of the tubes are attached to a horizontal plate for supply of the coolant.

Description

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Title: Method and device for sublimating / condensing an aqueous fluid.

The present invention relates to a method for sublimating or condensing an aqueous fluid in an enclosed space, in which sublimation / condensation tubes are placed at a mutual distance, vertically and substantially parallel, and wherein said method comprises the following steps; cooling the sublimation / condensation tubes, using a coolant fluid film, on the inner wall of those sublimation / condensation tubes; supplying aqueous fluid to that space through an inlet, after which said aqueous fluid sublimes or condenses on the sublimation / condensation tubes.

The method of the type mentioned in the introduction is known, inter alia, from European patent application EP 0.127.982. The known system is used, inter alia, for maintaining a vacuum in, for example, deacidification, bleaching and deodorization during the production of edible oils and fats. In these processes, steam, the so-called stripping steam, is supplied to the underside of a container containing fat, at a temperature of about 200 ° C. In the stripping steam, by-products and impurities (fatty acids) from the raw material are dissolved. These deacidification, bleaching and deodorizing processes work best when the container has the lowest possible pressure above the fat, for example about 10 millibars or less. In order to maintain this vacuum, the water vapor with dissolved impurities and by-products, the so-called process gases, must be removed at the top of the fat. Since impurities are present in the process gases (for example stench), the process gases cannot simply be extracted and emitted. The process gases must therefore not only be removed, but contaminants must also be removed from the process gases. In the dry condensing system, these process gases are therefore supplied to condensation pipes placed horizontally in a casing and filled on the inside with a refrigerant, for example ammonia. The process gases will then condense, at least in part 1005540 2, on the outside of these condensation tubes and then freeze or sublimate directly on the outer wall of the tubes. This process is also known in the state of the art under the name "dry condensing". Due to this condensation and / or sublimation, the process gases are effectively discharged from the container and the vacuum is retained in the reaction vessel, as desired.

During the sublimation / condensation process, the ice layer on the outside of the condensation tubes will grow. The energy consumption of a dry condensing system depends inter alia on the temperature difference between the saturation temperature of the process gases and the evaporation temperature in the cold-cooled condenser. The higher this temperature difference, the higher the energy consumption of the cold generator of the dry condenser. This temperature difference depends inter alia on the following three components.

In the first place, the higher the difference between the saturation pressure of the feed of the process gases and the saturation pressure in the condenser, the greater the temperature difference. Secondly, that temperature difference depends on the temperature difference between the evaporating refrigerant and the outer surface of the sublimation / condensation tube. This depends, among other things, on the efficiency of the heat transfer from the pipe wall to the refrigerant. Third, an increasing thickness of the ice layer that forms on the condensation tubes produces an increasing temperature difference.

The above makes it clear that one of the first conditions for low energy consumption of the dry condensing system is to de-condense the condenser relatively often.

An important drawback of the method according to EP 0.127.982 is that when the ice layer on the outside of the tubes has become too thick, the tubes are de-iced with the aid of hot air, which is introduced into the closed space around the tubes. . The hot air effectively removes the ice layer on the pipes. Before a new condensation cycle can be started, however, the closed space around the pipes must be evacuated again and again. With vacuum vacuuming time and time again, valuable operating time of the plant used is lost.

Fat and fatty acids will also be present in the water vapor to be condensed. These fats and grease residues cannot be removed from the tubes as easily as 1005540 3 the ice layer formed on the tubes. A second important drawback of the method according to EP 0.127.982 is that no measures have been built into this known method to specifically remove the difficult-to-remove deposits on the outside of the pipes.

It is the object of the present invention to provide a method in which water-containing fluid is condensed and / or sublimed on the wall of pipes, wherein this method provides an effective way of periodically de-icing and cleaning those pipes.

That object is achieved in the present invention in that said closed space is subsequently connected to a vessel containing fluid containing water.

The effect of this measure is that the vapor temperature in the system is very low due to the low temperature of the condensation tubes and the low pressure around the tubes. As a result, the fluid present in that vessel can boil spontaneously. The resulting water vapor precipitates on the ice and the condensation tubes and in this way the ice is removed from the condensation tubes.

After de-icing, the water in the enclosed space around the pipes can be drained away. The water remaining in the space, or residual water vapor and the like, will sublimate and / or condense on the outer walls of the pipes when a new sublimation / condensation cycle is started.

According to the present invention, it is possible that the vessel contains relatively cold water, with a temperature of at least 0 ° C.

For many applications it is sufficient if that vessel contains water with a temperature higher than 0 ° C. With the aid of the water and a temperature of at least 0 ° C, the ice on the sublimation condensation tubes can be effectively removed, provided that the ice contains relatively few impurities. This is the case, for example, when a method according to the invention is used for the production of vacuum ice. For example, the vessel of water used for de-icing the sublimation condensation tubes can be filled with ground water, which is extracted from the environment. Further devices for heating or cooling that water are not further necessary.

According to the present invention, it is possible for that vessel to contain relatively warm water.

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For example, the temperature of the water used to de-icing the sublimation condensation tubes may have a temperature of 60 °. This is desirable when the method of the present invention is used for the aforementioned deacidification, bleaching and deodorizing processes. In the ice deposited on the sublimation condensation tubes, fats and / or fatty acids will usually be present. By heating the tubes to, for example, 60 ° C, the fatty acids become thinly liquid. The ice melted in this way is discharged with the fatty acids at the bottom of the condenser.

According to the present invention, said closed space can be connected at the bottom to a drain tank.

The effect of this measure is that the melted ice and the condensed water vapor are discharged at the bottom of the enclosed space and supplied to a drain tank. When the aqueous fluid processed in the present method contains a certain amount of fat, this fat will float on the water in the drain tank and can be separated from the water there.

The method of the present invention is further improved by subsequently building a fluid film on the outside of the sublimation / condensation tubes.

The fact that not only a fluid film is built up on the inside of the tubes, but that a fluid film can also be built up on the outside of the tubes has the great advantage that the tubes can be cleaned by means of a fluid flow after the ice has been removed from the tubes. Due to the fluid flow along the outside of the tubes, these can be effectively cleaned.

Furthermore, according to the present invention, it is possible for that fluid film to be built up with water from the vessel with relatively warm water.

The advantage of this measure is that, for example periodically, the outside of the tubes is rinsed clean with relatively warm water. Any dirt residues and the like on the outer wall of the pipes are effectively removed by the warm water.

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It is also possible according to the present invention that said fluid film is built up with water from the vessel with relatively cold water.

After de-icing the pipes, the temperature of the pipes has risen far above the operating temperature for the sublimation / condensation process. Certainly 5 if pipes have been de-iced with a fluid with a temperature of about 60 ° C or if the pipes have been rinsed clean with water of that temperature, the temperature of the pipes must be lowered with the aid of, relatively expensive coolant, before sublimation- / condensation process can be restarted. By now rinsing the pipes on the outside with water from the relatively cold vessel (for instance filled with groundwater), the first part of the cooling step does not have to be effected by a cooling installation. Lowering the temperature of the pipes, for example from 60 ° C to 20 ° C, can then be carried out with relatively cheap water. Due to this measure, the cooling capacity required to cool the pipes after de-icing can remain relatively small.

An energy-saving measure is achieved by connecting this enclosed space to a pre-cooling / thawing tank containing water with a relatively low temperature, and then building a fluid film on the outside of the sublimation / condensation tubes, with water from that pre-cooling / defrosting tank.

For example, the pre-cow thaw tank contains water with a temperature of about 20 ° C. By connecting this tank to the closed space around the pipes, due to the low pressure, part of the water in the pre-cooling / thawing tank will boil. The water in the tank cools down to 5 ° C. The tubes themselves heat up during this process step. To be able to start up sublimation / condensation of process gases again using the sublimation / condensation tubes, the warm sublimator / condenser 1 must be cooled. This is then done by rinsing the pipes on the outside with the help of water that has dropped in temperature from the pre-cow thawing tank. Certainly when the tubes are also heated with the aid of water from the relatively warm vessel, the temperature of the tubes can be brought down considerably by this flushing. In this way, the cold generated when the pre-cow thaw tank was connected to the enclosed space is regenerated. Due to this regeneration process, the heat does not have to be removed by means of a cooling machine.

According to the invention, it is possible to heat the sublimation / condensation tubes 1005540 6, after connecting the enclosed space to the pre-cooling / thawing tank, using the compressed gases from the ammonia compressor.

In order to keep the energy consumption of the sublimation / condensation process of the present invention low, it is possible according to the present invention that the portion of that aqueous fluid that does not sublimate or condense against the tubes near the upwardly directed end of the tubes the pipes are guided and thereby cooled.

The water-containing fluid (process gases) to be supplied to the sublimator / condenser may, for example, contain inert gases or other gases which do not sublimate / condense in the system. For example, in the prior art systems, such fluids can accumulate at the top of a condenser and not flow past the cooled condensation tubes. In any case, the gases will not remain near the condensation tubes. In order to ensure that as little fluid as possible is discharged from the condenser, it is required that all the fluid has in any case been allowed to sublimate or condense.

The non-sublimated and / or the non-condensed fluids are extracted, for example through openings directly next to the sublimation / condensation tubes. This means that any unsublimated or condensed fluids contained in the top of the sublimator / condenser have been conducted past the tubes and have been cold in any case.

The applicability of the method according to the present invention is further increased when the refrigerant used in the installation is a type of brine, for example pekasol.

This has the advantage that a non-hazardous refrigerant is used in the system. Storage of the refrigerant therefore does not present any danger.

The present invention also relates to an apparatus for performing the above-described method.

Such a device is known, inter alia, from the aforementioned European patent application EP 0.127.982. This known device comprises a casing, a number of sublimation / condensation tubes arranged in that casing substantially parallel, substantially vertically and at a mutual distance, which, at the upwardly directed end thereof, comprise connections for the supply of refrigerant and at the downward end of those tubes, connections for the discharge of that refrigerant and a connection for the supply of the aqueous fluid to the free space around the sublimation / condensation tubes in that casing, said sublimation / condensation tubes with the top of which 5 are attached to a substantially horizontally placed first plate, all this in such a way that coolant present on the plate will flow into the sublimation / condensation tubes.

The device according to the present invention is characterized in that the device comprises a connection by means of which the closed one can be connected to a vessel containing fluid containing water.

The presence of a connection to a vessel containing water with a temperature of more than 0 ° C ensures that the sublimation condensation tubes can be de-iced from the vessel with the aid of that water.

In the device according to European patent application EP 0.127.982, the sublimation condensation tubes were de-iced using warm air. As noted above, the supply of warm air into the enclosed space is very disadvantageous, because with each new start of a sublimation condensation operation the enclosed space must be evacuated again.

In order to ensure that a fluid film 20 can build up on the outside of the tubes, it holds for an advantageous embodiment of the sublimator / condenser according to the present invention that the outside of said sublimation / condensation tubes near the the upper end thereof, below said first plate, are enclosed by a substantially horizontally placed second plate, with openings being provided between said second plate and said sublimation / condensation tubes, such that fluid present on the plate between the plate is provided. and flow the sublimation / condensation tubes.

This embodiment has the advantage that the means by which a fluid film is formed on the outside of the sublimation / condensation tubes can simply be supplied via an opening located above the second plate and this fluid will find its way downwards along the tubes. In this way, the formation of a fluid film on the outside of the sublimation / condensation tubes can be realized in a simple and inexpensive manner.

Furthermore, according to the present invention, it is advantageous that the free space between the sublimation / condensation tubes and between the sublimation / condensation tubes and the wall of the casing, is completely closed off near the bottom of those tubes by means of a plate, the device further comprising a drain extending at least from the top of that plate to the bottom of the casing.

The advantage of this measure is that during de-icing the melt water can collect on the said plate. Because a Drain is positioned from the top of the plate to the bottom of the enclosure, the melt water can be drained from the enclosure independently of the refrigerant flowing from the bottom of the sublimation 10 / condensation tubes.

Furthermore, it is advantageous according to the present invention that said drain is arranged to be connected to the supply of a drain tank.

The advantage of this measure is that the melt water, possibly containing residues of fat and the like, can be supplied to a drain tank. In the drain tank 15, the melt water and the fats present therein can be separated.

It is important, as mentioned previously, that the non-sublimated or non-condensed fluid to be removed from the sublimator / condenser has at least been cold. This can be advantageously achieved in that the second plate completely closes off the free space between the sublimation / condensation tubes and that casing, except for the openings provided between the tubes and the second plate, and that between the first and the second plate discharge means are provided for the discharge of those components of the aqueous fluid which do not sublimate / condense on the sublimation / condensation tubes.

The effect of this measure is that the non-sublimated or non-condensed fluid is at least passed close to the sublimation / condensation tubes and will therefore be cooled strongly. Only those fluids that do not sublimate or condense, even after the forced contact with the sublimation / condensation tubes, will be drained.

The operation of this system is further improved when the openings 30 between the second plate and the tubes are coated to prevent ice from forming.

The effect of this measure is that the gaps between the second plate and the sublimation / condensation tubes remain ice-free at all times and the passage of non-sublimed and non-condensed fluids will not be obstructed.

The operation and construction of the sublimator / condenser according to the present invention are elucidated with reference to the following figures, in which: Figure 1 shows a process diagram for carrying out the method according to the invention, including the sublimator / condenser according to the invention .

Figure 2 is a detail drawing of the sublimator / condenser of the present invention.

Figure 3 shows an alternative process diagram for performing the method of the present invention including the sublimator condenser of the invention.

Figure 1 shows a process diagram in which the sublimator / condenser 1 according to the present invention is incorporated. The sublimator / condenser 1 comprises at least some vertically placed sublimation / condensation tubes 2. These sublimation-15 / condensation tubes are closed from the outside by means of a casing 3. The sublimation / condensation tubes are attached with their upward-facing end to a substantially horizontally placed first plate 4. Below that plate 4, the sublimation / condensation tubes are enclosed by a substantially horizontally placed second plate 5. Openings 6 are provided between said second plate 5 and those sublimation 20 / condensation tubes 2, all this such that fluid present at the location 5 can flow between the plate 5 and the sublimation / condensation tubes 2 under the influence of gravity.

The operation of the sublimator / condenser 1 is as follows. With the products of edible oils and fats, steam, the so-called strip steam, is supplied to the bottom of a container (not shown on the drawing) containing fat, with a temperature of approximately 200 ° C. The stripping steam is passed through the fat, for example to rid the fat of impurities. In the container there is a space above the grease containing very low pressure, for example on the order of 10 mb ar or less.

To maintain this process it is advantageous if the vacuum above the fat is maintained as much as possible. The process gases in the space above the grease contain many impurities and cannot simply be removed and expelled, for example by means of a fan or pump. Pollutants (eg odor) must be removed from the process gases. For this purpose, the space with the process gases contained therein is connected to the condenser / sublimator 1 according to the present invention. The process gases flow into the sublimator / condenser 1 according to the present invention via the inlet 7, according to the arrow 10. The sublimation / condensation tubes 2 are cooled on the inside by means of refrigerant. This refrigerant, for example pekasol or NH3, is supplied from a cold buffer 15. From the cold buffer 15, the refrigerant is transported via pipes to the top of the sublimator / condenser 1. The refrigerant will flow into the 10 vertically placed sublimation / condensation tubes via the first plate 4 under the influence of gravity. The refrigerant entering the sublimation / condensation tubes 2 in this way will be removed from the device again at the bottom of the sublimator / condenser 1. Due to the film of refrigerant that builds up on the inside of the sublimation / condensation tubes 2, the tubes 2 will be cold on the outside. The process gases entering the sublimator / condenser 1 will therefore sublimate or condense on the outside of the sublimation / condensation tubes 2 and freeze later. In this way a layer of ice forms on the outside of the vertically placed tubes 2. The use of the sublimator / condenser 1 in this way effectively moves the process gases from the process space to the sublimation-20 / condensation tubes 2.

Since the efficiency of the sublimator / condenser 1 directly depends on the amount of ice that forms on the outside of the vertically placed tubes 2, the device must be defrosted regularly. When the sublimator / condenser 1 is thawed, the supply of process gases can be temporarily stopped, or the process gases 10 can be supplied to a second sublimator / condenser according to the present invention (not shown). In order to thaw the ice layer which has formed on the vertically placed tubes 2, the sublimator / condenser 1 according to the present invention is connected to a vessel with relatively hot water 16, containing water of for instance a temperature of 60 °. When this vessel 16 is connected to the sublimator / condenser according to the present invention, the water in the relatively warm buffer 16 will boil immediately, given the low pressure in the sublimator / condenser 1. The water vapor created in this way will condense on the outside of the vertically placed pipes 2 and the ice layer 1005540 11. This will melt the ice on the outside of the vertically placed tubes 2. The melted ice and the condensed water vapor will be discharged at the bottom of the sublimator / condenser 1 through drain 51 and will be fed to a drain tank 17. Due to the fact that the process gases 5 contain a certain amount of fat, it will also go to the drain tank 17 fed wastewater contain a certain amount of fat. This grease will be located at the top of the water in the drain tank 17 and can be separated from the water there.

Since the process gases 10 do not consist of pure water vapor, but also contain 10 impurities, a layer of dirt will build up on the outside of the vertically placed pipes 2. In order to be able to clean the pipes 2 on the outside, the sublimator / condenser 1 according to the present invention is connected via pipes between the first and the second plate to a water reservoir 18 containing water with a temperature which is, for example, equal to the outside temperature. . The reservoir 18 can, for example, be filled with groundwater that is extracted from the environment of the device. The supply of water from the reservoir 18 to the sublimator / condenser 1 has two advantages. First, the water will flow down the second plate 5 along the outside of the sublimation / condensation tubes. Impurities that may still be on the outside of these pipes 2 are washed away by the water and the vertically placed pipes 2 are thereby cleaned. Secondly, the fluid film built up on the outside of the vertically placed tubes 2 in this way will pre-cool the tubes 2. This means that when the tubes 2 have de-iced and have been heated to, for example, a temperature of 60-60 °, the first part of the cooling section, which must be used to be able to re-use the sublimator / condenser for sublimation and condensation. process gases, does not need to be done by means of refrigerant from the buffer 15, but can be done with the help of water coming from the buffer 18. That means that the first cooling range from eg 60 ° to 20 ° can be done with this cooling water. Since the stock from the buffer 18 can be extracted from the environment, no cooling installations are required for this. Due to this provision, the total cooling capacity required for the operation of the sublimator / condenser 1 according to the present invention can remain relatively limited.

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In order to keep the energy consumption of the sublimator / condenser 1 according to the present invention low, it is important to minimize the amount of non-sublimated or non-condensed fluid to be discharged from the sublimator / condenser 1. The water-containing fluid (process gases) to be supplied to the sublimator / condenser 1 may, for example, contain inert gases or other gases which do not sublimate / condense in the system. Therefore, in the sublimator / condenser 1 according to the present invention, means are provided to discharge these non-sublimating or condensing gases at the bottom of the sublimator / condenser 1. For this purpose, the space between the first plate 104 and the second plate 5 is connected via pipes to, for example, an ejector 20.

Steam is supplied to this ejector 20 according to the arrow 21, whereby gas can be transported via the venturi effect from the sublimator / condenser 1 in the direction of the condenser 22. Since the non-sublimated and the non-condensed gases at the top of the sublimator / condenser 1 are discharged, these gases are drawn near the upwardly directed end of the vertically positioned condensation / sublimation tubes 2 between the second plate 5 and the tubes 2. This means that the gases are in any case guided close to the outer wall of the tubes 2 and that in turn means that the gases have in any case been cold. This means that the gases that are discharged via the ejector 20 have at least a minimum volume.

Figure 2 shows a part near the upwardly directed end of the tubes 2 of the sublimator / condenser 1. Figure 2 shows that cavities 6 exist between the tubes 2 and the second plate 5. When gases are discharged by means of the ejector 20 from the space between the first plate 4 and the second plate 25 via the conduit 24, these gases will be drawn through the narrow gap 6 between the tubes 2 and the second plate 5. In order to prevent the gases from condensing and freezing on the outer wall of the tubes 2 at this location, it is provided with a coating 23. This coating may, for example, comprise a plastic, in any case it will be a material that forms an ice layer 30 on the outside of the coating 23 will counteract. This results in the opening 6 between the second plate 5 and the tube 2 remaining open at all times.

The energy consumption of the sublimator / condenser 1 according to the present invention can be further improved by the embodiment shown in figure 1005540 13 3. The operation of the sublimator / condenser 1 according to figure 3 is comparable to that of figure 1, with the difference that use is made of the regenerative pre-cooling / defrosting principle. The operation of the system according to figure 3 is as follows. Process gases from, for example, a deodorization process are supplied to the sublimator / condenser 1 via the inlet 7, according to the arrow 10. As with the device according to figure 1, a part of the process gases will condense / sublimate on the vertical beam of sublimation / condensation tubes 2 in the sublimator / condenser 1. When a certain amount of ice has deposited on the outside of the sublimation / condensation tubes 2, the supply of process gases is stopped. Unlike the process shown in figure 1, the inlet 7 of the sublimator / condenser 1 is then not connected to a vessel with relatively hot water 16, but to a pre-cow defrost tank 30. In this pre-cooling / defrosting tank 30 there is water with a temperature of about 20 ° C. Due to the low pressure in the sublimator / condenser 1, part of the water in the pre-cow Defrost tank 30 boils and then cools the water in the tank 30 from about 20 ° C to about 5 ° C. The sublimator / condenser 1 heats up due to the condensation effects. The melt water coming from the tubes 2 flows from the sublimator / condenser 1 to the drain tank 17. It is possible, but not necessary, to further heat the sublimator / condenser 1 to a temperature of about 30 ° C using of the compressed gases from the ammonia compressor 32. Subsequently, the inlet 7 is connected to the vessel with relatively warm water 16. The temperature of the sublimator / condenser 1 thereby rises to, for example, 60 ° C when there is water in the vessel 16 of approximately 80 ° C. The extra condensate that is formed here will also be drained to the drain tank 17.

25 In order to restart the sublimation / condensation of process gases in the sublimator / condenser 1, the warm sublimator / condenser 1 must be cooled down. This is done in the first place by supplying the water from the pre-cooler thaw tank 30 to the sublimator / condenser 1 below the first plate 4 and above the second plate 5. As can be seen in figure 3, the vessel 18 is missing, which 30, for example, is filled with groundwater. The temperature of the water from the pre-cow Defrost tank 30 is about 5 ° C. With the aid of this relatively cold water, the sublimator / condenser 1 can be cooled from about 60 ° C to about 20 ° C. In this way, the cold generated when the pre-cool Wont 1005540 14 thaw tank 30 was connected to the inlet 7 to heat up the sublimator / condenser 1 is regenerated. Due to this regeneration process, the heat does not have to be removed by means of a cooling machine. The great advantage of this method is that a relatively large amount of energy is saved. The water that flows from the sublimator / condenser in this process step is returned to the pre-cooling / thawing tank 30.

The pressure in the drain tank 17 is below atmospheric and is equal to the instantaneous pressure in the sublimator / condenser 1 when the sublimator / condenser 1 is connected via the inlet 7 to the pre-cow Defrost tank 30 or to the vessel with 10 relatively warm water 16. The melt water in the fatty acids (condensate) in the drain tank 17 is discharged when a maximum level is exceeded, by pressurizing the tank 17 with the aid of steam. The steam is supplied according to the arrow 34. The content of the drain tank 17 thereby flows into the tank 31. In this tank 31 (with an atmospheric pressure) there is thus water with fatty acids, which float on the surface thereof. Some of the water is used to supply the pre-cooling / thawing tank 30 and the vessel with relatively warm water 16, since the evaporation losses from these tanks must be made up. The amounts of water and fatty acids that eventually flow from the tank 31 to a waste water purification are equal to the amounts of concentrated stripping steam and fatty acids 20 and the total amount thereof is therefore minimal.

The great advantage of the embodiment as shown in figure 3 is that energy is saved by using the regeneration process of the pre-cow Defrost tank 30.

The sublimator / condenser 1 according to the present invention can be used not only for example in the production of oils and fats, but also in the production of so-called vacuum ice. In such a process (not shown), a vacuum with a low pressure, for example on the order of 6 mbar, exists in a reaction vessel above an aqueous fluid. That pressure of 6 mbar is equal to the saturation pressure of water vapor at 0 ° C. When a pressure is maintained in the reaction vessel above 6 mbar above the water-containing fluid, ice can be effectively produced with a relatively low amount of energy. The process space above the aqueous fluid will therefore be able to be connected to a sublimator / condenser 1 according to the present invention. The sublimator / condenser that could be used for this ice cream manufacture basically has the same design as the sublimator / condenser 1 shown in figure 1. However, not all parts indicated in figure 1 are required to operate the sublimator / condenser 1. according to the present invention to operate in the production of vacuti ice cream. Since there will be no oils and fats in the water vapor extracted from the process space above the water-containing fluid, the condensate that will form on the outer wall of the vertically placed sublimation / condensation tubes 2 will not contain any fats or oils. . Therefore, in the production of vacuum ice, in which the sublimator / condenser according to the present invention is used, to defrost the sublimator / condenser 1, it is not necessary to de-ice the vertically placed sublimation / condensation tubes 2 with a relatively warm buffer. 16, as was necessary in the production of, for example, oils and fats. When using the sublimator / condenser 1 of the present invention for ice cream production, thawing of the vertically positioned sublimation 15 / condensation tubes 2 can in principle take place at 0 ° C, with atmospheric pressure. The vessel 16 shown in Figure 1 with relatively warm water therein could be omitted from the system. De-icing could be done with water that is extracted from the environment, for example groundwater as can be found, among other things, in buffer 18.

Another similarity with the use of the sublimator / condenser 1 according to the present invention in the production of oils and fats is that ammonia is preferably used as a refrigerant in the production of vacuum ice cream. The vertical positioning of the sublimation / condensation tubes 2 has the advantage when using ammonia that relatively little ammonia has to be used in the sublimator / condenser 1. After all, the tubes 2 are not completely filled with ammonia, but the construction of a fluid film on the inside of the tubes 2 is sufficient for the operation of the sublimator / condenser 1. This means that relatively little ammonia is used in the system. and that means that the risks associated with the use of ammonia in the facility are also limited.

It is noted that the device according to figures 1 and 3 are usually designed with more than one sublimator / condenser (for example two), so that the supply of the process gases, after the supply of the gases to sublimator / condenser 1 has been shut off, to a other sublimator / condenser can be led.

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The operation of the sublimator / condenser 1 according to the present invention, of course, does not change by connecting another production process to the inlet 7. However, the process diagram shown in Figure 1 could be left simpler as explained above.

5

The examples shown above provide options for using the sublimator / condenser of the present invention. Of course, this list is not exhaustive. There are many other options in which the sublimator / condenser can be used that fall within the scope of the following claims.

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Claims (17)

A method for sublimating or condensing a water-containing fluid in an enclosed space, in which sublimation / condensation tubes (2) are placed at a mutual distance, vertically and substantially in parallel, and said method comprising the following steps; cooling the sublimation / condensation tubes (2) using a refrigerant fluid film on the inner wall of those sublimation / condensation tubes (2); 10. supplying aqueous fluid to that space through an inlet (7), after which said aqueous fluid sublimes or condenses on the sublimation / condensation tubes (2); characterized in that said enclosed space is subsequently connected to a vessel (16, 18, 30) containing fluid containing water. Method according to claim 1, characterized in that said vessel (18) contains relatively cold water, with a temperature of at least 0 ° C. Method according to claim 1 or 2, characterized in that said vessel (16) contains relatively warm water. Method according to claim 1, 2 or 3, characterized in that said enclosed space is connected at the bottom to a drain tank (17). 25 Method according to one of the preceding claims, characterized in that a fluid film is subsequently built up on the outside of the sublimation / condensation tubes (2). A method according to claim 5, characterized in that said fluid film is built up with water from the vessel (16) with relatively warm water. A method according to claim 5, characterized in that said fluid film is built up with water from the vessel (18) with relatively cold water. Method according to claim 1, 4 or 5, characterized in that said enclosed space is connected to a pre-cooling / thawing tank (30) containing 5 water of a relatively low temperature, and that the sublimation is then applied to the outside of the sublimation. - / condensation tubes (2) build up a fluid film, with water from that pre-cooling / thawing tank (30). Method according to claim 8, characterized in that 10. the sublimation / condensation tubes (2) are heated with the aid of the compressed gases from the ammonia compressor (32). A method according to any one of the preceding claims, characterized in that the portion of said aqueous fluid that does not sublimate or condensate against the tubes near the upwardly directed end of the tubes (2) along the tubes (2) is guided and thereby cooled. A method according to any one of the preceding claims, characterized in that said refrigerant is a type of brine, for example pekasol. 20 An apparatus for sublimating / condensing an aqueous fluid, comprising a sheath (3), a plurality of in said sheath (3) substantially parallel, substantially vertical and spaced sublimation / condensation tubes (2) comprising at the upward end thereof connections for the supply of refrigerant and at the downward end of those pipes (2) comprising connections for the discharge of that refrigerant and a connection (7) for the supply of the water-containing fluid to the free space around the sublimation / condensation tubes (2) in that sheath (3), said sublimation / condensation tubes (2) being attached with a top side thereof to a substantially horizontally disposed first plate (4) this in such a way that refrigerant present on the plate (4) will flow into the sublimation / condensation tubes (2), characterized in that the device comprises a connection by means of which the closed to be connected to a vessel (16, 18, 30) containing water-containing fluid. 1005540 4 13. Device as claimed in claim 12, characterized in that the outside of said sublimation / condensation tubes (2) near the upwardly directed end thereof, below said first plate (4), are enclosed by a second plate placed substantially horizontally (5), openings (6) being provided between said second plate (5) and said sublimation / condensation tubes (2), such that fluid present on the plate (5) between the plate (5) and the sublimation - / condensation pipes (2) can flow. Device according to claim 12 or 13, characterized in that the free space between the sublimation / condensation tubes (2) and between the sublimation / condensation tubes (2) and the wall of the casing (3) is close to the underside of those tubes (2) is completely closed by means of a plate (50), the device further comprising a discharge (51) running at least from the top of that plate (50) to the bottom of the casing (3). Device according to any one of claims 12, 13 or 14, characterized in that said drain (51) is arranged to be connected to the supply of a drain tank (17). 20 Device according to any one of claims 12 to 15, characterized in that said second plate (5) completely seals the free space between the sublimation / condensation tubes (2) and that envelope (3), except for the openings which are provided between the tubes (2) and that second plate (5), and that between the first (4) and the second plate (5) discharge means are provided for the discharge of those components of the aqueous fluid which do not sublimate / condense on the sublimation / condensation tubes (2). Device according to any one of claims 12 to 16, characterized in that said openings (6) between the second plate (5) and said tubes (2) are provided with a coating (23) which forms the of an ice layer. / 1005540 'I'