FI74619B - FOERFARANDE OCH ANLAEGGNING FOR AOTERVINNING AV LOESNINGSMEDEL. - Google Patents

Description

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Method and apparatus for solvent recovery

The invention relates to a method and an apparatus for recovering solvents. In known methods and apparatus described, for example, in "Ullmanns Enzyklopädie der technischen Chemie", Part 1 (1951), page 338, in an evaporation or evaporation chamber, a carrier gas stream loaded by solvent vapors is cooled to dissolve the solvent vapors and condense. The steam-poor carrier gas stream after reheating is returned to the evaporation chamber. In this case, the solvent vapors do not completely condense away from the carrier gas stream; a certain residue of solvent vapor corresponding to the evaporation pressure of the solvent at the temperature of the coolant still remains in the carrier gas stream. To avoid solvent losses, the carrier gas stream is therefore recirculated. As a result, the capacity of the solvent vapors of the solvent vapor-poor carrier gas stream is slightly reduced as a result, which is, however, insignificant for the economics of the method.

The method is generally suitable for the separation of volatile solvents from non-volatile substances.

The scope is the removal of solvent residues from chemical substances prepared or purified using solvents. Other applications include paints and varnishes, dry cleaning or cleaning of textiles, films and foils, natural rubber processing and adhesives and binders.

Known equipment generally uses separate cooling devices to condense solvent vapors and other devices to reheat solvent vapor-poor carrier gas streams, requiring considerable amounts of cooling media on the one hand and high energy to reheat the solvent vapor-poor carrier medium on the other. This reheating of the carrier gas stream is necessary so that it can quickly receive a sufficient amount of solvent vapor again in the evaporation state, i.e. that the base material dries faster.

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An attempt could now be made to achieve energy savings by using a cooling medium to reheat the solvent vapor-poor carrier gas stream, which heats up as it passes through the cooling device, i. the refrigerant-5 is led against the carrier gas stream. However, it must be seen that in this way only a small fraction of the heat previously removed from the cooling device can be fed into the carrier gas stream. Due to the relatively small temperature difference between the carrier gas and the refrigerant, the cooling device and the device used to reheat the carrier gas stream must be equipped with large heat transfer surfaces.

The method is disadvantageous not only because of its energy and refrigerant consumption, but also because of its high equipment costs.

DE-PS 27 25 252 further discloses an apparatus for recovering a solvent from a solvent vapor-depleted, i.e. enriched, warm carrier gas stream, in which the gas stream for condensing the solvent vapors 20 and separating the solvent is compressed, cooled and, in the course of the work, expanded, whereby the solvent vapor-poor carrier gas stream is returned to the evaporation chamber after reheating.

However, the recovery of this carrier gas stream takes place in the form of a mixture of carrier gas taken from the evaporation chamber and concentrated with solvent vapors. This is conducted when it is first heated by indirect heat exchange (heat transfer) with a compressed carrier gas stream in the conduit, together with a solvent vapor-poor carrier stream 30 back to the evaporation chamber. The aim is to achieve better heat control, which, however, has the disadvantage that the carrier gas stream returned to the evaporation chamber has a relatively high solvent vapor content. In this way, the drying effect of the evaporation chamber is reduced. DE-PS 27 25 252 further states that the work released during recovery in the expansion turbine can be recovered. However, there is no indication of where this work can be usefully exploited.

The object of the invention is to improve the above-mentioned method and apparatus to such an extent that, on the one hand, the work of expanding the compressed solvent vapor stream carried out with solvent vapor is utilized at low equipment costs and the carrier stream returned to the evaporation chamber is as low as possible.

The invention therefore relates to a process for recovering solvents, in which a solvent-vapor-loaded carrier gas stream in the evaporation chamber for condensing solvent vapors and separating the solvents is compressed to size, cooled and expanded during the operation, after which the solvent vapor depletion is carried out again. this method is characterized in that the working power obtained in the expansion is used by means of a mechanical coupling together with 20 externally imported work to compress the base loaded with solvent vapor and distributing the gas stream.

The invention further relates to an apparatus for carrying out this method, comprising an evaporation chamber connected to a carrier gas stream circulation, in which a heated carrier gas stream is loaded with solvent vapors, a compressor, a this apparatus is characterized in that the compressor is mechanically connected to the expansion machine and the external auxiliary working machine and that the cooling device and the reheating device consist of at least one heat exchanger through which the solvent vapor-poor carrier gas stream passes.

It is preferred that the expansion machine is mechanically connected directly to one of the two or more compressors.

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In the apparatus according to the invention, the carrier gas stream introduced into the circulation in the evaporation chamber (usually in a dryer) takes with it a large amount of evaporated solvent and the solvent is removed from the carrier gas stream again in a cooling device by cooling and condensing. Although in the known method the solvent vapor-depleted base gas stream is compressed and, after cooling, expanded during the work, the expansion work is not utilized in the system as a compression job, as is the case in the invention. Thus, only the difference between the pressing and expansion work from the outside has to be fed to the pressing step or to the second pressing step, i.e. by means of an additional external working machine which is directly mechanically connected either together with the expansion machine to the compressor or to another compressor. This separation covers the work required to separate the solvent vapor from the carrier gas stream and to overcome the losses (friction, transfer of cold to the environment).

The compression increases the particle density in the mixture of carrier-20 stream and solvent vapors. This increases the efficiency of the heat exchanger. Due to the reduced gas volume, the heat exchanger and other pressurized parts of the system can be kept compact. Finally, compression and expansion do not have a chemical, especially non-oxidizing, effect of solvent vapors, unlike recovery processes using adsorbents such as activated carbon. Such adsorbents can often cause the formation of decomposition products which have a detrimental effect on solvent vapors. Because the carrier-30 gas stream is constantly recycled, these decomposition products would become enriched and react undesirably with the products or equipment parts to be dried. One known case is the decomposition of chlorohydrocarbons in activated carbon in the presence of water vapor, whereby hydrogen chloride is formed.

In an embodiment with two or more pressing steps, these are preferably used separately with the co-fed work, i. one or other compressors are mechanically connected to external implements.

This arrangement allows better control of the compression process, e.g. better control of the desired final pressure. In addition, the dimensions of the required gear between the implement and the compressor can be kept small.

Expansion turbine is preferably used as the expansion machine, since it has a higher efficiency and can also be more easily connected to a compressor or another compressor or, for example, to a compressor drive motor, e.g. a piston machine. The additional working machine is preferably an electric motor.

The method according to the invention can be applied, for example, in the production of a surface adhesive material, in which case the adhesive is applied to paper or textile webs or tapes. Such tapes can be used, for example, as technical adhesive tapes or webs for medical purposes (e.g. an adhesive patch). In order to coat a paper or textile web with an adhesive, the adhesive is brought into a fluid state by means of liquid solvents so that it can be arranged in sufficiently thin and even layers. On drying, the solvent evaporates. To this end, the product remains in the evaporation chamber in contact with the carrier gas receiving the solvent vapors for a time determined by the volatility of the solvent and the amount used.

The application examples below apply to equipment for these specific uses. However, the invention is also successfully applicable to the other uses mentioned above.

30 As solvents for adhesives and for many other uses, solvents or solvent mixtures with flammable vapors are generally used. Therefore, according to the invention, a carrier gas with an oxygen content of 35 below the ignition limit is used for the recovery of such solvent vapors. For example, an inert gas such as nitrogen or carbon monoxide can be used for this purpose; also the oxygen content of the air can be reduced by mixing inert gas to such an extent that the ignition limit is no longer reached. In some cases, it is also possible to use a flue gas with a low oxygen content.

However, the flammability of solvent vapors is not only a function of the oxygen content of the carrier gas, but also depends on the concentration and type of solvent vapor. Thus, for example, the risk of ignition of low-boiling hydrocarbons and ethers is higher in halogenated hydrocarbons. The ignition properties of the various solvent vapors are known and can be found in the literature or the permissible solvent vapor concentrations and oxygen concentrations can be ascertained by simple experiments.

15 The use of an inert or oxygen-poor carrier gas stream offers the advantage that the carrier gas stream can be loaded with a large amount of solvent vapor without the risk of explosion. In this way, the amount of carrier gas to be recycled can be kept small so that the amount of energy required to cool and reheat the carrier gas 20 can be reduced.

The process of the invention is not limited to the recovery of organic solvents; it can also be applied to the recovery of inorganic solvents, such as ammonia and sulfur-oxide, such as those between organic and inorganic solvents, such as carbon disulphide or carbon tetrachloride. Since these solvents are non-combustible (with the exception of carbon disulphide), it is not necessary to maintain a certain oxygen concentration in the carrier gas in these cases, i.e. in the simplest case air can be used as the carrier gas.

Method control according to the invention, e.g. also taking into account the adaptation of the equipment to different solvents or solvent mixtures, it is possible in different ways. For example, the material to be dried to be transported through the evaporation space is 7 7461 9

The speed can be changed. Another control option is to change the carrier gas flow rate. For this purpose, the speed of the compressor or the drive motor of the compressors can be changed. For this purpose, a compressor bypass control can also be performed, i.e. control of the carrier gas flowing past it.

A particularly simple possibility to control the temperature of the solvent vapor-removed carrier gas stream is such that the gas is subjected to indirect heat exchange with the refrigerant before, between and / or after the individual compression steps. For this purpose, an indirect condenser can be connected between the evaporation chamber and the compressor or the first compressor, between the first and second or possibly subsequent compressors and / or between the compressor or the last compressor and / or the expansion machine. By controlling the flow of coolant in the condenser or condensers, the temperature of the carrier gas stream loaded by the solvent vapor to the compressor or the first compressor or subsequent compressors and / or the expansion machine can be

By connecting an indirect auxiliary cooler between the compressor or the last compressor and the expansion machine, it is possible for the solvent vapor-poor carrier gas stream to enter the evaporation chamber at a lower and better controllable inlet temperature.

The auxiliary cooler is usually connected in front of the heat exchanger through which the solvent vapor-poor carrier gas stream passes. However, this cooler can advantageously be connected in front of a heat exchanger ("warm heat exchanger") and after another heat exchanger ("cold heat exchanger"). In doing so, the carrier gas stream enters the evaporation chamber at a lower temperature.

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When the carrier gas-loaded carrier gas stream, after coming out of the compressor or the last compressor, is cooled in the cooling device, some of the solvent vapors can already be condensed off, which e.g. depends on the temperature of the solvent vapor-poor carrier gas stream used as refrigerant. For example, there is a possibility that water will separate out because it has a higher boiling point than many organic solvents. Although water is not used in solvent mixtures of conventional self-adhesive adhesives, it does enter the system because it is adsorbed on paper or textile webs used as substrates for the adhesive material. In some cases, it may even happen that the water freezes in the cold part of the heat exchanger or in the expansion machine, blocking the flow-15 cross-sections or damaging the moving parts of the expansion machine.

To avoid this danger, it is proposed to spray a liquid-soluble water-soluble solvent into a cooled carrier gas stream prior to expansion. When the solvent is dissolved in water, a solution is formed which has a lower freezing point than water and which remains liquid.

If the cold solvent is not dissolved in the water, the water settles on the surface of the cold solvent droplets and therefore cannot separate from them on the solid surfaces of the flow paths.

25 This is solved by installing devices between the heat exchanger and the expansion machine for injecting a liquid solvent into the carrier gas stream.

It is most convenient to spray a portion of the water-soluble solvent separated from the condensed and solvent separator into the cooled carrier gas stream.

If it is not desired to start spraying a liquid solvent or if there is a risk that the condensed liquid will damage the moving parts of the expansion machine, e.g. For this purpose, a second solvent separator can be placed between the heat exchanger and the expansion machine.

Another possibility for controlling the temperature of the carrier gas stream is such that, while performing the work, only 5 partially expanded carrier gas streams are inflated once more without performing the work; for this purpose, an expansion valve can be provided in front of the evaporation chamber. This expansion valve can be installed on either the inlet or outlet side of the heat exchanger. This expansion valve can also be used, e.g. for adjustment, in such a way as to prevent freezing in the pipelines going to the expansion machine or in the expansion machine itself.

By that time, there is little additional cooling in the carrier gas stream through the expansion valve without performing work in this case. The thus expanded carrier gas stream can now be used, possibly after the condensed solvent has been separated, in indirect heat exchange, working as the cooling gas stream of the expanded carrier gas stream. For this purpose, a second heat exchanger can be connected between the expansion machine 20 and the first solvent separator, through which the solvent vapor-poor carrier flow flows, in which case the expansion valve is placed immediately in front of this heat exchanger.

Some embodiments of the apparatus according to the invention will be explained with reference to the drawings, in which Figure 1 shows an apparatus with only one solvent separator and one cooler; Fig. 2 shows an apparatus with a condenser and two solvent separators and an additional heat exchanger between the first solvent separator 30 and the expansion machine; Fig. 3 shows an apparatus with an additional cooler between the compressor and the expansion machine, in which a heat exchanger is connected in front of this cooler and a heat exchanger is also connected behind it; Fig. 4 shows an apparatus with an additional cooler between the compressor and the expansion machine, in which only a heat exchanger is connected behind this cooler; Fig. 5 7461 9 shows an apparatus in which the expansion machine is connected directly to the second compressor, the first compressor being connected to an external drive motor; and Fig. 6 shows an apparatus in which the expansion machine 5 is connected directly to the first compressor, the second compressor being connected to an external drive motor.

In the embodiment according to Figure 1, a paper or textile web marked with the number 10 is provided with an adhesive coating dissolved in a solvent. The web 10 moves (in this unrecited elements through the use of) the direction of the arrow shown schematically in the evaporation chamber 12 therethrough. This is so enclosed that solvent vapors cannot enter the environment.

A warm, solvent-poor carrier gas stream 14, e.g. a nitrogen stream, is introduced into the evaporation chamber against the direction of movement of the paper or textile web 15. The heating of this carrier gas stream takes place as indicated below.

The warm carrier gas stream 14 flows through the evaporation chamber 12 against the direction of movement of the paper or textile web 10, thereby heating the web to such an extent that the solvent in the adhesive solution evaporates (indicated by reference LMv in the drawing). The carrier gas stream is then loaded with solvent vapors, which cools due to the heat of evaporation of the solvent. When n-hexane-25 is used as the solvent, the inlet temperature of the gas stream to the evaporation chamber 12 is e.g. 140 ° C and the outlet temperature is about 100 ° C. The discharged solvent vapor-loaded carrier gas stream 16 now enters the condenser 18, through which the coolant 20 flows in an indirect heat exchange connection. The flow rate of the coolant-30 and thus the temperature of the carrier gas stream 16 loaded with solvent vapors can be controlled by the throttle valve 22. In the assumed example, the throttle valve 22 is adjusted so that the carrier gas stream exiting the condenser 18 has a temperature of about 34 ° C as the refrigerant 20 heats up from about 12 to about 65 ° C.

An expansion valve 38 can be used to further control the temperature of this carrier gas stream. As the carrier gas stream 7461 9 passes through this valve, additional cooling occurs without operation. Thus, in addition to the throttle valve 22, the temperature of the system can also be controlled by the expansion valve 38 in a simple manner. With both of these valves, the system can be adapted to the widest possible range of solvent combinations without other control devices. The cooling of the carrier gas stream in the expansion valve is used in the alternative of Figure 2 to cool the carrier gas stream after the expansion turbine 30, which is discussed in more detail below.

The cooled carrier gas stream now enters the compressor 24, where it is compressed by a factor of about 2.5 as its temperature then rises to about 140 ° C. After the compressor, the carrier gas stream 16 goes to a heat exchanger 15 26, where it is cooled by indirect heat exchange with a solvent vapor-poor carrier gas stream 14 (in the example to -10 ° C). In the heat exchanger (exchanger) 26 some of the solvent vapors are already condensed and the mixture marked 28, which consists partly of solvent vapor-concentrated carrier stream-20 stream, liquid solvent particles and possibly ice parts, can be fed to the expansion turbine 30. 34) to remove liquid and solid particles. As a result of the work performed in the expansion turbine 30, further cooling of the carrier gas stream takes place and the mixture of solvent vapor-poor carrier gas stream, liquid solvent particles and possibly ice particles marked 32 enters the solvent separator 34, where the mixture 32 is separated.

The compressor 24 and the expansion turbine 30 are suitably located on a common shaft driven by the motor 36. Thus, the work performed in the expansion turbine 30 can be utilized practically without loss to compress the carrier gas stream 16 loaded with solvent vapor in the compressor 35. The motor 36 is the only energy source in the system. The solvent vapor depleted carrier gas stream 14 exiting the solvent separator 34 is in the illustrated embodiment 7461 9 at a temperature of about -40 ° C and flows through the heat exchanger 26 in indirect heat exchange with the solvent vapor-loaded carrier gas stream 16. The former is then heated to about 140 ° C, i.e. to the temperature required to evaporate the solvent 5 in the evaporation chamber 12.

In the solvent separator 34, as mentioned above, the mixture is separated into a solvent-poor carrier gas stream 14 and a liquid solvent (possibly solid ice particles in the mixture). The liquid solvent is removed through line 40. Most of the liquid solvent is used to prepare the adhesive solution. To do this, it may be necessary to separate the water from the solvent or to readjust the ratio between the individual solvent components to the initial ratio. But in general, the average ratio of solvent components to steady state remains constant when it is in a stable state of operation, because the evaporation chamber 12 is so well sealed that no solvent vapors escape during use. The recovery of most of the recovered solvent is indicated by dashed line 42.

A small portion of the recovered solvent is passed down line 44 to pump 46 and sprayed to heat exchanger 26 and / or mixture 28 prior to expansion machine 30. As already mentioned, this solvent portion prevents the connection line 28 of heat exchanger 26, expansion machine 30 and 25 from freezing, that the solvent forms a low-melting mixture with water or ice separates from the cold solvent droplets. The solvent supply lines are marked 48a and 48b, respectively.

The embodiment according to Figure 2 corresponds to the alternative of Figure 1 with respect to the order of the individual components up to the heat exchanger 26. However, after the heat exchanger 26, a second solvent separator 50 is provided before the expansion turbine 30. The primary function of this solvent separator is to separate away the water and the high-boiling components of the solvent mixture. After passing through the expansion turbine 30, a mixture 32 of solvent vapor carrier gas and liquid solvent is passed through a second heat exchanger 52 to a solvent separator 34. In this alternative, the expansion valve 38 is located immediately downstream of the solvent separator 34. As it passes through this expansion valve, the carrier gas stream cools without working power, further separating the solvent 5 which can be removed in the solvent separator 51. The cooled carrier gas stream 14 can be used as a coolant in the second heat exchanger 52. heated to the required temperature in the evaporation chamber 12.

The use of the co-solvent separator 50 reduces the risk of solvent droplets or ice particles damaging the impeller of the expansion turbine 30. Nevertheless, a smaller portion of the solvent separated in the solvent separator 34 may be sprayed through the line 44, pump 46, and line 48a or 48b into the heat exchanger 26 or gas-liquid mixture 28 to avoid freezing of the heat exchanger or line 28.

In the embodiments shown in Figures 3 and 4, elements which are identical or equivalent to the elements of the embodiments of Figures 1 and 2 are given the same reference numerals. The main difference is that an indirect cooler 25 25 is connected downstream of the compressor 24. This indirect cooler can be used to simply lower the temperature of the solvent vapor-poor carrier gas stream entering the evaporation chamber, e.g. for n-hexane to about 70-100 ° C. . If this temperature drop were to be achieved in the embodiments 30 of Figures 1 and 2, the carrier gas stream in the cooler 18 would have to be cooled to such an extent that its temperature should only be up to about 10-20 ° C before entering the compressor 24. By using the cooler 25, the temperature of the carrier gas stream can also be controlled over a wider range, namely by appropriately controlling the coolant valve 29.

In the embodiment according to Figure 3, a heat exchanger 26a ("warm" heat exchanger) is connected in front of the radiator 25, followed by a heat exchanger 26b ("cold" heat exchanger). The solvent vapor-poor carrier gas stream flows through both of these heat exchangers. A bypass valve 27 is connected in parallel to the heat exchanger 26a. If this valve is opened, part of the carrier gas stream goes to the heat exchanger 26a, whereby the temperature of the carrier gas stream in the evaporation chamber decreases by that time. In this way, too, it is possible to adjust the temperature in a simple manner.

In order to keep the temperature of the solvent vapor-loaded carrier gas stream 10 constant in the "cold" heat exchanger 26b (in the case of n-hexane at about 20 ° C), the mass flow of coolant through the auxiliary cooler 25 must be increased with the valve 27 open.

Figure 3 shows a solvent separator 50 placed in front of the expansion machine. This solvent separator is only necessary when the carrier gas stream has a high solvent vapor concentration and the amount of solvent separated after the heat exchanger 26b is so large that solvent damage to the expansion machine 30 is feared.

In the embodiment of Figure 3, the cooler 18 may be provided with a second valve 23, by means of which the flow rate of the solvent vapor-containing carrier gas stream can be adjusted.

In addition, a drain valve 39 for condensed solvent is installed in the discharge line 25 of the solvent separator 34. This, as in the embodiments of Figures 1 and 2, can be returned to the heat exchanger 26b or the cooler 25 if there is a risk of ice formation.

It can also be seen from Figure 3 that the motor 36 30 is connected via a gear 54 to a common shaft between the compressor 24 and the expansion-turbine 30. My expansion peat is preferably guided. The compressor 24 is preferably threaded.

The embodiment according to Figure 4 mainly corresponds to the embodiment according to Figure 3. It has only one heat exchanger 26 after the additional cooler 25. That is, it lacks a front-mounted heat exchanger 26a. A bypass valve 27 is connected in parallel to the heat exchanger 15 7461 9 26 in the same way as at the heat exchanger 26a of Fig. 3, by means of which and the valve 29 it is possible in a simple manner to regulate the solvent vapor-poor carrier gas inlet temperature to the evaporation chamber.

Also in the embodiment of Fig. 4, a solvent separator can be placed in front of the expansion machine 30 in the same way as the separator 50 of Fig. 3. In addition, the solvent separated in the solvent separator 34 can be removed to the drain valve 39 and partially returned if there is a risk of freezing in the heat exchanger 26.

The arrangement according to Fig. 5 substantially corresponds to the arrangement according to Fig. 1. The cooled carrier gas stream coming out of the condenser 18 goes to the first compressor 15, which is forcibly or frictionally connected to an electric motor 36 acting as an external machine via a clutch. The electric motor speed can be adjusted according to the low temperature required for condensation or After the compressor 23, the carrier gas stream 16 goes to a second compressor 24, which is directly mechanically connected to the expansion machine 30 (converted turbocharger), which is indicated by a continuous shaft marked 31. The compressed carrier gas stream 16 now enters a heat exchanger 26a ("warm" heat exchanger) where it is cooled in indirect heat exchange by a solvent vapor-poor carrier gas stream 14. The heat exchanger 26a is, as in the embodiment of Figure 3, An indirect cooler 25 is connected behind the heat exchanger 26a, by means of which the temperature of the carrier gas stream can be adjusted in a simple manner. Without the cooler, the carrier gas stream 16 would have to cool in the cooler 18 to such an extent that its temperature before entering the compressor 35 should be only about 10-20 ° C. To do this, the radiator 18 would have to be built quite large. With the inclusion of the cooler 25, the temperature of the carrier gas stream 16 16 61 9 9 can also be adjusted over a wider range by suitably controlling the coolant valve 29.

A heat exchanger 26b ("cold" heat-5 exchanger) is connected downstream of the condenser 25, as in the embodiment of Figure 3, in which the carrier gas stream is again cooled in indirect heat exchange by a solvent vapor-poor carrier fraction stream 14 (in the example to about 0 ° C). The temperature control of the solvent vapor carrier gas stream 14 is possible by means of a bypass valve 27.

10 In order for the temperature of the solvent vapor-depleted carrier gas stream in the "cold" heat exchanger 26b to remain constant (about 0 ° C in the case of n-hexane), the mass flow of coolant through the auxiliary cooler 25 must be increased with the valve 27 open.

15 Some of the solvent vapors are already condensed in the heat exchanger 26b. This part is removed in the solvent separator 50.

However, this is only necessary when the solvent vapor content of the carrier gas stream is high and the amount of solvent separated after the heat exchanger 26b is so large that damage to the expansion machine 30 is feared due to the solvent droplets.

The mixture of solvent vapor-rich carrier gas stream numbered 28 and any liquid solvent particles still present flows into an expansion machine 30 formed into an expansion turbine 25 (converted turbocharger). This is, as already mentioned, mechanically connected to the compressor 24 by means of a shaft 31. thus, virtually no losses are utilized in the compressor 24 to compress the solvent-rich carrier gas stream, since no power transmission losses occur. The motor 36, which drives the first compressor 23, is the only external energy source in the system, so that the energy supply can be flexible according to the current needs of the system.

As a result of the work carried out in the expansion turbine 30, additional cooling of the carrier gas stream takes place, and the mixture marked 32 consisting of the solvent vapor-poor 17 7461 9 carrier gas stream and any liquid solvent particles still present (proportion greater than 28) goes to the solvent separator 34. the carrier gas stream 5 is in the assumed application example at a temperature of about -40 ° C and flows successively through the heat exchangers 26b and 26a in indirect heat exchange with the solvent vapor-rich carrier fraction stream 16. In this case, the former is heated to about 140 ° C, i.e. to the temperature required to evaporate the solvent vapor-10 in the evaporation chamber 12.

To further control the temperature of this carrier gas stream, an expansion valve 38 may be provided. As the carrier gas stream passes through this valve, additional cooling occurs without operation. Thus, the temperature of the system can be controlled not only by the throttle valve 22 but also by the expansion valve 38 in a simple manner. With both valves, other control devices can be adapted to the widest possible range of solvent combinations without the use of other control devices. The cooling of the carrier gas stream 20 present in the expansion valve 38 can be used to cool the carrier gas stream after the expansion turbine 30 (not shown in the drawing), whereby a solvent separator can be installed behind the expansion valve 39 if necessary.

In the solvent separator 34, as in the embodiment of Fig. 1, the mixture is divided into a solvent-poor carrier gas stream 14 and a liquid solvent, which, as in the embodiment of Fig. 1, is further treated.

If necessary, a smaller portion of the recovered solvent 30 can be passed through line 44 to pump 46 and sprayed to heat exchanger 26b and / or mixture 38 before expansion machine 30. As already mentioned, this water soluble solvent portion prevents heat exchanger 26b, expansion machine 30 and connecting line 28 from freezing. that the solvent forms a low-melting mixture with water or that ice separates from the cold solvent droplets. The solvent supply lines are marked 48a and 48b, respectively. Freezing of the expansion turbine 30, as well as the risk of solvent droplets or ice particles damaging the expansion turbine impeller, is also reduced by the solvent separator 50.

In the embodiment shown in Figure 6, elements which are identical or equivalent to the elements of the applets of Figures 1 and 5 are provided with the same reference numerals. The main difference is that the expansion machine 30 is mechanically connected directly to the first compressor 23 10 (by means of a shaft 31) while the second compressor 24 is connected to the electric motor 36. This arrangement has the advantage over the arrangement of Figure 1 that the solvent vapor pressure or temperature can be further controlled. before it enters the "warm" heat exchanger 15a, because the deviation from the target values can be resisted at this point by direct control by means of the motor 36 and the counter-control acts immediately.

In addition, in this embodiment, the expansion machine 30 is formed as a line-driven expansion turbine, which provides additional control capability and optimizes the efficiency of the expansion turbine according to the current pressure and flow conditions in the system. Finally, a valve 21 is mounted in front of the compressor 23 as a control element.

The invention is not limited to the described application examples, but can be modified in various ways without departing from the scope of the invention.

Claims (20)

A method for recovering an evaporated solvent, wherein the warm carrier gas stream loaded by the solvent vapor in the evaporation chamber for condensing solvent vapors and separating the solvents is compressed, cooled and expanded in a known manner, after which the solvent vapor depletion is carried out. the working power obtained in the expansion is used by means of a mechanical coupling together with the work imported from the outside to compress the carrier gas stream loaded with solvent vapors. A method according to claim 1, characterized in that the working power obtained in the expansion is transferred by means of a direct mechanical connection to one or more compression steps for compressing the carrier gas stream loaded with solvent vapors. Method according to Claim 2, characterized in that the second or other pressing steps are operated separately by the externally fed work. Process according to one of Claims 1 to 3, characterized in that an inert gas or a gas having an oxygen content below the ignition limit of the solvent vapors is used as the carrier gas. Method according to one of Claims 1 to 4, characterized in that the temperature of the carrier gas loaded with solvent vapors is controlled before, between and / or after the individual compression steps by indirect heat exchange by means of an external cooling medium. Process according to one of Claims 1 to 5, characterized in that a water-soluble solvent in liquid form is sprayed onto the cooled carrier gas stream before expansion. 7461 9 A method according to claim 6, characterized in that a part of the condensed and separated solvent is used for spraying the cooled carrier gas stream. Process according to one of Claims 1 to 7, characterized in that a part of the solvent vapors is condensed and separated from the cooled carrier gas stream before expansion. Method according to one of Claims 1 to 8, characterized in that, when the work is carried out, only the partially expanded carrier gas stream is expanded once more without carrying out the work. A method according to claim 9, characterized in that the expanded carrier gas stream 15 is used in indirect heat exchange as the cooling gas of the expanded carrier gas stream. An apparatus for carrying out the method according to any one of claims 1 to 10, wherein an evaporation chamber is connected to the carrier gas circuit 20, in which the heated carrier gas stream is loaded with solvent vapors, a compressor, a cooling device for condensing solvent vapors that the compressor (24) is mechanically connected to the expansion machine (30) and the external auxiliary machine (36) and that the cooling device and the reheating device consist of at least one heat exchanger (26 or 26a and 26b) 30 through which the solvent vapor-poor carrier gas stream passes. Apparatus according to Claim 11, characterized in that the expansion machine (30) is mechanically connected directly to one of the two or more compressors (23 or 24). Apparatus according to Claim 11, characterized in that the second or other compressors are mechanically connected to external working machines (36), 21 „Λ, 7461 9 Apparatus according to Claim 11, 12 or 13, characterized in that the expansion machine (30) is an expansion turbine and the additional working machine (36) is an electric motor. Apparatus according to Claim 11, 12, 13 or 14, characterized in that between the evaporation chamber (12) and the first compressor (23), the first and second or respective compressors and / or the last compressor (24) and the expansion machine (30) an indirect cooler (18 or 25) is connected in between to control the temperature of the carrier gas stream loaded by the solvent vapors 10. Apparatus according to Claim 15, characterized in that a heat exchanger 15 (26a) is connected in front of the indirect cooler (25) mounted between the compressor or the last compressor (24) and the expansion machine (30) and is followed by a heat exchanger (26b). Apparatus according to one of Claims 11 to 16, characterized in that devices (48) for injecting a liquid water-soluble solvent 20 into the carrier gas stream are arranged between the heat exchanger (26) and the expansion machine (30). Apparatus according to one of Claims 11 to 17, characterized in that a second solvent separator (50) is arranged between the heat exchanger (26) and the expansion machine (30). Apparatus according to one of Claims 11 to 18, characterized in that an expansion valve (38) is arranged in front of the evaporation chamber (12). 19 7461 9 Apparatus according to one of Claims 11 to 19, characterized in that a further heat exchanger (52) is connected between the expansion machine (30) and the first solvent separator (34), through which the solvent vapor-poor carrier gas stream passes, and that the expansion valve (38) is immediately a solvent separator (51) is arranged in front of this heat exchanger and behind the expansion valve (38). 7461 9