DE1292635B - Process for the continuous separation of mixture components - Google Patents

Description

The invention relates to a method for continuous separation of mixture components using a separation column.

Among other things, it is already used for the enrichment of mixture components known, the required separation in rectification columns, ion exchange columns, To carry out gas scrubbers and the like. However, these processes have a common disadvantage indicates that the speed of the necessary exchange of substances is essentially is determined by diffusion processes. These diffusion processes take place more firmly and liquid phase are very slow and determine the rate of mass transfer. The slow exchange of substances, in turn, often makes very extensive separation systems necessary. Accordingly, there have so far been numerous, per se effective separation effects, z. B. those based on crystallization, the application of the continuous Multiplicative working method not accessible on the scale of technical operation. The same applies to liquid-liquid extractions.

It is a process for the continuous separation of mixture components known from an at least two-phase mixture, the middle range the mixture fed to the separating column while maintaining at least two phases periodic Changes of state is subjected, and the resulting differences in density the phases are used to transport the components of the mixture in countercurrent.

It is also known to generate periodic pressure changes by means of perforated pistons, above all an intimate mixing of a molten phase moving in countercurrent to the crystals, which is intended to facilitate the rinsing of the mother liquor from the crystals. It is here generated by piston pressure fluctuations in the low level, which in turn are used for the purpose of phase transport.

The invention relates to a method for continuous separation of mixture components from an at least two-phase mixture using a separating column, the mixture fed in in the middle region of the separating column subject to periodic changes of state while maintaining at least two phases and the resulting differences in density between the phases for transporting the The components of the mixture to be enriched are used in countercurrent. The procedure is through characterized in that the periodic state changes are uniform within causes the entire separating column executed pressure and / or temperature fluctuations will.

In the method according to the invention, the pressure changes are preferred executed adiabatically.

In this method, the changes in state occur to such an extent that the quantity ratio of the phases follows the fluctuations over time, the flow and return in the separating space being adapted to the fluctuations so that the differences in density of the phases are used to transport the mixture components to be enriched. The fluctuations in the physical state variables to be used according to the invention relate primarily to fluctuations in pressure and / or temperature over time or in the concentration dependent thereon. One advantage of the invention is the achievable increase in separation effects (in the area of so-called " theoretical trays") in separation apparatus. In the previously known methods, the multiplication of the individual separation steps takes place in that a mixture present in two phases passes through a series of stationary states in countercurrent. The disadvantage here is, inter alia, that the phases which come into contact with one another are almost in physico-chemical equilibrium and therefore the differences between the activities of the components in the two phases that cause the separation process remain small. The invention, on the other hand, makes it possible to realize larger deviations from equilibrium conditions by periodically changing the operating conditions within the entire separation space and thereby to repeat the separation process several times in the area of each of the theoretical trays of the separation space, while maintaining the continuous mode of operation of the separation apparatus. The periodic change in the operating conditions leads to fluctuations in the phase relationship, which result in a relatively low depreciation of the energy.

It is surprising and very advantageous when using the invention also that the time fluctuations superimposed on the continuous separation process not only do not disturb the operating conditions, they even automatically optimize them Adjust separation effects. Compared to the known stationary method according to the invention The existing advantage of higher sales per unit of time is based, among other things, on that at every location of the separation space due to the periodic fluctuations over time the operating conditions briefly deviate far greater from the equilibrium conditions occur than is the case with the stationary procedure. Through the procedure according to the invention is a periodic build-up and breakdown of the whole separation space existing phases brought about, whereby the mass transfer is very accelerated.

The phase relationships are from the diagram in FIG . 1 can be found.

Given is a mixture of the total concentration xo at temperature t and the pressure pl in the form of phases 1 and H. The concentration of a component of the mixture in phase I has the value yl, its concentration in phase II has the value xi . If now z. B. by an adiabatic pressure change the mixture in the area of higher pressure p. and the automatically corresponding higher temperature t. , brought, then, according to the phase equilibria that are different under these conditions, phase II remains in its area of existence. Phase 1, however, splits off a certain amount of phase II from concentration x2, with its own concentration of y increasing to the larger value y. increases. If the conditions p, and t, are now approximated again sufficiently quickly, a smaller, but enriched amount of phase, I of the composition y2 remains , which is carried on by the countercurrent, while the increased amount of phase II of the Composition between x, and x. at the temperature t, and the pressure pl, the phase 1 with the composition y, is again split off, with its composition again approaching the value x. The proportion of the phases has changed during this process.

There are four different cases of such cycles, which for theoretical reasons should be referred to as second-order phase cycles, in the present example, which are to be derived in accordance with the description above. The cycle described as an example would only have no effect if the two phases were always in equilibrium during it, i.e. That is, if the periodic cycles were to run so slowly that all the concentration differences within the individual phases equalize, which is not the case under normal operating conditions (in the case of the example for phase II).

For the practice of the invention in the case of treatment of mixtures with liquid and gaseous phases can be proceeded roughly as follows will.

In an ascending stream of two gases, drops of liquid move downwards, which contain both components, with a slow exchange of the volatile component takes place from the liquid against the less volatile component from the gas phase. If a periodic pressure fluctuation is carried out, then condenses in the Compression period a certain amount of vapor, both components are not in the same Contains ratio as it is in the liquid. When removing the Pressure, there is no re-evaporation of a corresponding amount of liquid, because as a result of the transport of the drop that has now occurred and as a result of the In the gas phase, the rapid diffusion of the droplets is already in a another environment that is richer in the non-volatile component. By The exchange of substances between gas and liquid is along a certain cycle Distance significantly accelerated.

The advantages of the method according to the invention are also particularly evident clearly stands out when dealing with mixtures in which conversions between the liquid and solid phase made to enrich one component of the mixture should be, z. B. in the treatment of seawater to freshwater. During execution this method is, for example, the procedure that in a column in which Ice crystals move upwards and brine downwards, pressure fluctuations occur will. When the pressure increases, a certain amount of the still salty melts Ice to low-salt water. This occurs due to the required heat of fusion of the ice, a corresponding cooling. If the pressure drops again, it arises from this low-salt solution, an ice with a much lower salt content, which the current of the descending Brine rises in the opposite direction to layers with less salt. The heat of fusion released in the process lets the temperature rise again. With the next pressure surge, this lower salt melts Ice again, but this time in a lower-salt environment, and from this again with less salt The resulting solution creates an even purer ice during the subsequent relaxation. The pressure fluctuations follow because of the consumption or the release of the heat of fusion of the ice is the temperature in the separation space according to the p-T diagram of water.

The same effect can be achieved with the reverse current device of the Phase, achieve with those substances in which an increase in pressure leads to crystallization and a decrease in pressure causes melting.

A system for obtaining fresh water from sea water is shown in the schematic FIG . 2 can be found.

In a column 1 there are internals such. B. perforated floors or spatially meshed sieves 2. The inlet 3 for the seawater to be treated, the overflow 4 for the fresh water obtained and the outlet 5 for the running brine are connected to the column. The three lines 3, 4, 5 lead through a heat exchanger 6. A compressor 7 is inserted in the line 3 , and an expansion device 8 and 9 , respectively, in the lines 4 and 5. Part of the energy occurring in the expansion devices 8, 9 is transferred to the compressor 7 in a manner not illustrated in greater detail and covers part of the required compressor output. The system works as follows, for example: there is already a mixture of ice and salt solution in the column at a temperature of -4 ° C. and therefore atmospheric pressure. In the line 3 sea water is fed and by means of the compressor 7 to the operating pressure of z. B. 200 atm compressed. The pressure can be lower or higher. In the heat exchanger 6 , the sea water is simultaneously z. B. cooled to -61 C.

If the seawater inlet 3 is opened, the pressure in the column rises to the mentioned, z. B. 200 atm. In this way, the ice in the column is caused to melt, at the same time an exhaust cooling to - 21 C occurs. Since the salt content of the ice is known to be 10 1 / o of the salt content of the mother liquor due to adhering layers and due to inclusions, the salt content of the solution in the melting zone is lowered by a ratio of 10: 1 .

When certain amounts of ice crystals, which have accumulated below the next higher soil, which forms a barrier for them, as a result of their weight buoyancy, have melted, part of the lighter fresh water accumulated in the upper section of the column is pressed out through the overflow 4 when the compressed sea water is still flowing in . After switching off the spill 4, the column is, by opening the flow relaxed 5, wherein the pressure in the column back to atmospheric pressure and simultaneously the temperature back to - 41 C increases. Here, a certain amount of ice forms on each floor, which rises to the next higher floor and is stopped by this. The process cycle described can be repeated continuously.

The temperature of the fresh water pressed out of the column is about -6 ° C, and the water arrives at the heat exchanger at about this temperature. The temperature of the brine in the power train between the column 1 and heat exchanger 6 is between - 6 and - 4 'C; at the beginning of the working cycle described, it is about - 61 C, increases during the game and at the end of the game at about - 41 C.

The readily understandable, schematic state diagram for the sake of clarity according to FIG. 3, with the coordinates of pressure, temperature and composition of the water-table salt mixtures, shows the work process identified in the following state and work scheme. Work scheme for the separation of water from salt solutions State in the operation Separation space pl, t, feed and melting by pressure p2, t2 inlet and overflow P21 t2 drain, freeze and return pl, t, The running brine can in turn be used to obtain z. B. of table salt, magnesium salt, bromine salt and other substances contained in it can be beneficially recycled.

Claims (2)

Patent claims: 1. Process for the continuous separation of mixture components from an at least two-phase mixture using a separating column, the mixture fed in the middle area of the separating column being subjected to periodic changes of state while maintaining at least two phases and the resulting density differences of the phases for the transport of the mixture components to be enriched serve in countercurrent, characterized in that the periodic changes in state are brought about by pressure and / or temperature changes carried out uniformly within the entire Trenu column. 2. The method according to claim 1, characterized in that the pressure changes are carried out adiabatically.