CH703522B1 - Blow-off system for solvent. - Google Patents

Abstract

The invention relates to a device and a corresponding method for removing solvent vapor from substances dissolved in solvents from fractionation vessels of a bleed system (100) by means of a carrier gas (50), wherein carrier gas is fed to each fractionation vessel by means of a respective injection device (3), wherein by means of a discharge device (7) of the Abblassystems (100) with solvent vapor laden carrier gas of the plurality of fractional container is collected and removed, by means of flow barriers of the discharge (7) cross-contamination between fraction containers by return of collected solvent vapor (8) is prevented.

Description

The invention relates to a method for the removal of solvents from dissolved substances by blowing with a carrier gas and a blowing system with a blowing device for supplying a stream of a carrier gas in the solution containing a container and the surface of the substance solution and discharge means for removing the solvent vapor with loaded carrier gas.

description

In the isolation of substances in the synthesis laboratory, the last step is usually an evaporation process in which the purified and dissolved substance must be freed from the solvent. Different methods are used for the removal of the solvent, which are different in efficiency or time-consuming depending on the boiling point of the solvent to be removed or evaporated. The goal is usually to remove the solvent at the lowest possible temperature, which is why it is generally carried out under reduced pressure, which reduces the boiling point of the solvent.

In the method of concentration, the solvent at elevated temperature, i. usually> 25 ° C, evaporated under reduced pressure, condensed again in a condenser and collected in a template. For classical concentration (= evaporation of the solvent) of individual samples with volumes of 10 ml to 50 l, the so-called rotary evaporator is frequently used.

When lyophilizing or freeze-drying the solvent, the dissolved sample is first frozen and then the solvent removed by sublimation under vacuum.

The concentration of a solution by blowing off the solvent vapors over a liquid can then be used when a dissolved substance is to be freed from the solvent under mild conditions. For this purpose, a gas stream is passed over the liquid surface, which removes the evaporating solvent in the over-blown gas stream.

In preparative liquid chromatography mixtures of substances are separated into the individual components, which are thereby collected in dissolved form as individual fractions in individual fraction containers. For the removal of the solvent from the individual fractions (usually in cylindrical Fraktioniergläsern) again the different evaporation methods are used, but this is technically much more demanding than the concentration of individual samples, especially when many fractions must be evaporated.

If the removal of the solvent under inert and gentle conditions, i. without heating, the solvent can be blown by blowing in an inert gas, e.g. Remove nitrogen, using a rake-type distributor with hollow needles in each of the individual fraction.

The saturated with solvent vapor gas stream is blown in an open system in the exhaust air of a trigger or blown through a condenser in the exhaust of a fume hood or in a closed circuit through a condenser and re-recording of solvent vapor in the injection device (rake type distributor Essay).

A disadvantage of these blow-off methods, however, is that the saturated with solvent vapor gas stream, which emerges from the individual juxtaposed Fungus, merges directly above the Fractionation, wherein a cross-contamination with substance particles take place in the adjacent Fraktioniergläser by backflow of the collected gas stream can.

The invention has for its object to provide a blow-off system for solvents available, which is free of the aforementioned disadvantages. In particular, a system is to be proposed which permits contamination-free isolation of substances from substance solutions in several fraction containers by blowing off.

According to the invention the object is achieved by a method for removing solvent vapor by means of a carrier gas from a plurality of fraction containers of a Abblassystems and for isolating dissolved in the fractionation vessels in solvent substances, as defined by the features of claim 1. In particular, by means of a discharge device of the Abblassystems the solvent vapor laden carrier gas of the plurality of fraction containers are discharged, wherein the carrier gas is supplied separately to each fraction container by means of a Einblaseinrichtung, wherein by means of Ableitkanal the diverter the leakage of solvent-laden with carrier gas carrier is separated, each discharge with a collection channel of the discharge device is connected, by means of which the Ablertstrom each discharge channel is collected and removed in a collecting stream, each discharge channel having a flow barrier, by means of which a return flow of the collecting stream is prevented in the Ableitkanäle and contamination to be isolated substances.

One of the advantages of the invention is that the isolated, separate removal of carrier gas from the individual fraction containers prevents mutual contamination by entrainment of substance-laden steam between the fraction containers arranged close to each other. The isolation of the individual substances is ensured.

According to a preferred embodiment of the invention, an inert gas, e.g. Nitrogen, circulated by the pump in a closed circuit. At the point of evaporation, solvent vapors are taken up by the system gas at ambient temperature or elevated temperature and recondensed in the condenser, which is cooled. The "dried" gas is first thermostatted after the condenser in a heater and returned to the evaporation site for renewed vapor absorption.

In the following, a preferred embodiment of the invention will be described with reference to the accompanying drawings. Show it: <Tb> FIG. 1 <SEP> is a schematic representation of a closed bleed system for an xy array of fraction containers; <Tb> FIG. 2a <SEP> a schematic representation of the placement of a discharge device on the fractionation glasses; <Tb> FIG. 2b is a schematic representation of the attached discharge device in the region of the upper opening of a single fraction container; <Tb> FIG. 3 <SEP> is a schematic representation of an embodiment variant of the blow-off system, wherein discharge pipes connected to the discharge device and designed as pipe sections are introduced into the individual fraction containers; <Tb> FIG. 4 is a schematic representation of a detail of a discharge barrier formed as a flow barrier from FIG. 3; <Tb> FIG. FIG. 5a shows a schematic representation of the discharge pipes to be introduced into the fraction containers and FIG <Tb> FIG. Figure 5b is a schematic representation of the discharge tubes inserted into the fractionation vessels.

As shown in Fig. 1, there is a series of fractionating glasses 1 in a heated water bath 2. For the evaporation of a liquid, that is, for a liquid to be in the gaseous state, the so-called heat of evaporation is necessary. The heat of evaporation is specific depending on the type of liquid. In order that the temperature of the original from which the solvent is blown off can be kept at a constant temperature and does not rapidly cool, the evaporation pattern in a heating bath (water bath) 2 is kept at a constant temperature, i. thermostated by means of a heater 20.

Instead of a thermostated water bath, the fractionating glasses can also be heated by a thermostatically controlled gas stream or by heating radiation.

The fractionating containers or glasses 1 are in a rack in defined positions, i. for example, arranged at equal intervals from one another in the x and y directions. A rake-like arrangement of a series of hollow needles 30 with the positions of the fractionating glasses 1 corresponding distances at a distributor or at a blowing device extends into the individual fractionating glasses. The injection device 3 has a supply line 5, via which a carrier or system gas is supplied by means of a circulating pump 6. The gas exits at the ends of the hollow needles and passes over the liquid surface. It rips the supernatant solvent vapors with it. In a closed circuit, the input of the circulating pump 6 is connected to an outlet of a condensation device 9, from which the carrier gas is taken over.

About the openings of the glasses is a discharge device 7, here also Abblasaufsatz or collector called arranged, which brings together the back from the individual glasses gas flowing and via a hose 8 to a condenser 9 (intensive cooler) leads. The condenser serves to cool the system gas enriched with solvent vapor to such an extent that the solvent vapors condense out. The cooling coils 10 of the condenser are cooled by means of a cooling medium of a cooling unit such that the condensation temperature is below the temperature at which the solvent is evaporated and blown off, advantageously 0 to -20 ° C. The condensing solvent is collected in a receiver 11 at the lower end of the condenser.

The dried carrier gas is sucked at the upper end of the condenser of the circulation pump 6 and returned via the supply line 5 in the vessels with the solvent, where it can absorb solvent again. The design of the circulation pump must be such that, for example, no oil residues can enter the system gas, i. So for example a diaphragm pump.

For blowing off several vessels, e.g. fractionation glasses, which are arranged in a rack in the x and y direction, the discharge device 7 consists of a flat-shaped cavity 12, which connects on its underside via openings 13 to the individual fractionating glasses, as shown in Figs. 2a and 2b is apparent. The cavity carries at one end an outlet 14, via which it is connected to the condenser 9 via the hose 8. There may be multiple outlets 14. A rake with hollow needles 30 can be retracted over the upper side of the outlet 14 in such a way that the lower ends of the hollow needles can be moved downwards when the solvent level drops. The descendant of the rake can be done manually or automatically via a drive.

So that the dried system gas flows as optimally as possible over the liquid surface in the fractions, the rake with the hollow needles by means of a drive (not shown) is driven continuously downwards. However, the hollow needles must never touch the liquid surface, otherwise there is a risk of contamination or fine solvent droplets could get into the discharge device 7. The control of the needle level can be time-controlled or sensor-controlled by means of a controller 40. In the control via a sensor 45, a fractionating glass is used as the "reference glass" which has the highest filling level, in which a sensor determines the liquid boundary or boundary line by contactless scanning and thus controls the setting height of the needle rake. The scanning is preferably carried out by a thermal sensor, which determines the largest temperature gradient, ie the locally greatest temperature change along the reference glass. The discharge device is designed to be adjustable in height and preferably driven by a motor. Based on the scan to determine the level in the reference glass, the hollow needles 30 can be dynamically tracked at a defined distance from the liquid surface.

The waste heat of the cooling unit can be used via a secondary circuit for the thermostatting of the evaporation vessels, for example in a water bath and the thermostating of the dried, recirculated system gas.

Since the vapor pressure of a solvent in the gas phase depends on the temperature, the recirculated gas is heated so far that on the one hand optimal gas absorption is made possible and on the other hand, however, the dissolved sample is not heated above a set temperature.

The gas stream can also be passed through an activated carbon filter and a particulate filter before it is returned to the fractions. The filter or filters are preferably arranged at the outlet of the condenser 9.

The Abblasaufsatz or the diverter 7 is precisely matched with the hole pattern for the fractionating so that they, as shown in Fig. 2a, can be moved into the hole pattern on the underside of the Abblasaufsatzes when lowering the Abblasaufsatzes. The vertical positioning of the fractionating glasses is set in such a way that the upper edges of the fractionating glasses in each case do not reach the upper end of the individual openings and thus close, so that gas which is blown into the fractionating glasses reaches the collecting level beyond the upper edge can.

The diverter 7 serves to remove the exhaust gases, i. to collect the solvent-laden towing gas from an xy array of fractionating glasses and to lead to a single outlet to which a large cross-section hose 8 is connected, which leads the gas to the condenser. The blow-off attachment is designed in such a way that this collection process does not lead to any carry-over, i. Contamination, leading in adjacent vessels.

The Abblasaufsatz is constructed such that it closes like a cover tightly with the heat transfer space, that is, it carries at the edge of a seal 15, which rests on the edge of the molded glass or Plexiglas pan 16. As a result, it is not necessary for each individual evaporation vessel to be hermetically sealed off with the collecting space through which the entrainment gas laden with solvent vapor is discharged. As a result, it is also possible to use vessels with larger or customary tolerances with regard to the outside diameter and glass thickness.

With each parallel concentration of fractions there is a risk of carryover from one fraction to another. This is particularly the case when evaporating under reduced pressure, where splashes or sudden bubble formation by dissolved gas in the liquid of the individual fractions can cause splashes from one fraction to the other. In the present method by blowing there is a possible risk of contamination, especially at the end of Einengprozesses. The conclusion of the Einengprozesses usually corresponds to a drying process in which loose particles of a crystalline substance can be whirled up by the gas flow and dragged.

As shown in Fig. 1, to prevent this contamination, the discharge device 7 is constructed such that the gas flow leaving the evaporation vessel is first passed through a narrow, descending space 17 on the outside of the evaporation vessel along in the collection plane. By means of this flow barrier, it is ensured that particles or fine liquid droplets which have fallen into the collecting plane are not dragged into an adjacent fraction container since they would have to move upwards against the gas flow along the outer wall of an adjacent vessel.

Since the fractionation glasses do not close tightly with the heat transfer space, it is expedient to flush this space before the blow-off with the towing gas or inert gas. For this purpose, the Abblasaufsatz be provided with a separate gas inlet, which leads directly into the heat transfer chamber. If gas is passed through this inlet before the blow-off process, this passes into the heat transfer space. The air displaced in this case can again pass along the glasses this time from the outside of the fractionating glasses into the collecting level. Excess gas supplied to the system can be removed via a valve.

After this gas exchange is completed for inerting, the inlet is closed and the blow-off process can begin.

Fig. 3 illustrates a schematic representation of a variant of the Abblassystems 100, wherein connected to the discharge device 7, designed as a pipe pieces discharge pipes 31 are introduced into the individual fraction container 1. The blowing device 3 of the blow-off system 100 has a carrier with a hollow needle 30 corresponding to the number and the position of the fraction container 1.

In addition, a discharge pipe 31 is arranged concentrically around each hollow needle. Each drain pipe is permanently connected to the carrier. The upper opening of each tube, together with the support of the discharge device 7, each form a narrow, descending space 17 which serves as a flow barrier, with blown carrier gas having to overcome this barrier and the barrier preventing backflow of the blown and solvent vapor laden carrier gas. Subsequently, the carrier gas which overcomes the respective flow barrier is collected in a collecting plane 72 or a collecting channel of the discharge device 7.

The serving as a flow barrier, narrow, descending space 17 is referred to here as Ableitkanal 71. It is formed from the cavity 12 and in each case the upper edge of a fraction container 1 or a discharge pipe 31. The upper edge of the fractionation container 1, usually a test tube, is also referred to as a collar. Gas blown out of the container moves in the direction of the arrow over this collar and down through the narrow space 17 into a collecting space or plane 72, from where the gas stream flows to the outlet 14. The discharge channel may also be formed as a tube with a small cross section, which is fed directly to the condenser 9, wherein the cross section and the length of the tube are formed such that a return flow of carrier gas is prevented.

The support of the injection device 3 has according to the number and the position of the fraction container 1 as a pipe pieces designed discharge pipes 31 which are inserted into the fraction container 1. In order to prevent carrier gas from escaping through the interspace between the fraction tank 1 and the discharge pipe 31, part of the supplied inert gas is conducted into the space 80, which forms the trough 16 and discharge device 7. In this case, the tub 16 and discharge device 7, which are arranged to be movable relative to each other, a closed and sealed by a sealing means 15 space.

The carrier of the injection device 3 is mechanically coupled in the present embodiment with the discharge device 7 or permanently connected thereto.

The reference numeral 19 denotes a heater for preheating carrier gas, whereby the fractionation tanks 1 evaporation energy is supplied. The carrier gas in the present embodiment preferably has a higher temperature than that of the solvent in the fractionation tanks 1.

In addition, a temperature coefficient is achieved at the solvent surface, which is detectable by means of a thermal sensor 45 for the purpose of determining the liquid level. The blow-off system 100 has for this purpose a measuring device 45 for continuously tracking the carrier with the hollow needles 30 in accordance with the drop in the solvent level in the fractionation containers 1.

4 illustrates a schematic representation of a single fraction container 1 with a discharge channel designed as a flow barrier from FIG. 3. The controllable device 45 dynamically determines the height of the solvent level of the glass 1 by detecting the largest temperature difference of the glass. The different temperatures of solvent and carrier gas also form on the outer surface of the fractionation vessel. Based on the thus dynamically determined solvent level or interface, the carrier can be tracked with the hollow needles 30 in accordance with the decrease of the solvent. The reference numeral 71 shows the discharge channel and the reference numeral 710 a corresponding leakage or Ableitgasstrom.

5a illustrates a schematic representation of the discharge pipes 31 and hollow needles 30 to be introduced into the fraction containers. The reference numeral 16 denotes the trough in which the plurality of fraction containers are present.

5b illustrates a schematic representation of the discharge pipes 31 introduced into the fractionation tanks. Reference 15 denotes a seal for sealing the tank 16 with respect to the discharge device 7. The discharge pipes 31 act like a telescopic extension of the fractionation tanks 1. Reference numeral 18 denotes a wall which together with the tub 16 and the seal 15 form a space 80. In the space 80, carrier gas can be introduced during the blow-off, so that a carryover of substance particles between the fraction containers 1 is prevented.

Reference numeral Legend

[0042] <Tb> 100 <September> blow-off <tb> 1 <SEP> Fraction container, fractionating glass <Tb> 10 <September> cooling coil <Tb> 12 <September> cavity <tb> 13 <SEP> Openings, recesses for fraction tanks <Tb> 14 <September> outlet <Tb> 15 <September> seal <Tb> 16 <September> Bathtub <Tb> 17 <September> Room <Tb> 18 <September> wall <Tb> 19 <September> Heating <tb> 20 <SEP> Heating, thermostat <tb> 2 <SEP> Heating bath, heating fluid <Tb> 3 <September> insufflation <Tb> 30 <September> hollow needle <tb> 31 <SEP> Drain pipe, pipe section <tb> 40 <SEP> Control, regulation <tb> 45 <SEP> Thermal sensor, detection means, sensor <Tb> 5 <September> lead <Tb> 50 <September> carrier gas <Tb> 6 <September> Grants <Tb> 7 <September> diverter <Tb> 71 <September> discharge channel <tb> 710 <SEP> Leakage current, discharge gas flow <tb> 72 <SEP> Collection channel, collection area, collection level <tb> 720 <SEP> Collection flow, collection gas flow <tb> 8 <SEP> Hose, pipe <Tb> 80 <September> Room <tb> 9 <SEP> Condenser, Condenser <tb> 90 <SEP> Filter, particle filter, activated carbon filter

Claims (15)

1. A method for removing solvent vapor by means of a carrier gas (50) from a plurality of fractional containers (1) of a Abblassystems (100) and for isolating in the fractionation containers (1) dissolved in solvents, wherein by means of a discharge device (7) of the Abblassystems (100 ) the carrier gas laden with solvent vapor is removed from the plurality of fraction containers (1), characterized the carrier gas is fed separately to each fraction tank (1) by means of a blowing device (3), in that a discharge stream (710) of solvent-laden carrier gas of each fractionation container (1) is diverted by means of a discharge channel (71) of the discharge device (7), that by means of the discharge device (7), the individual separate Ableitströme (710) are collected and discharged to a collecting stream (720), wherein by means of a respective flow barrier of a discharge channel (71) the return flow of the collecting stream (720) in the individual fraction container (1) and a contamination of the substance to be isolated is prevented. 2. The method according to claim 1, characterized in that the carrier gas (50) is conveyed in a closed circuit of the Abblassystems (100) by means of a conveying means (6), wherein the circuit further comprises: the injection device (3), the discharge device (7 ), a filter (90), a heater (19), a condensation device (9) for condensing the solvent transported by the carrier gas and that the carrier gas is supplied by means of discharge channel (71) directly or by means of the collecting channel (72) of the condensation device (9) , 3. The method according to any one of claims 1 to 2, characterized in that by means of a non-contact thermosensor (45) of the Abblassystems (100) dynamically local strongest temperature change of a solvent having fraction container (1) is detected, based on the detected temperature change by means of a Control (40) of the Abblassystems (100) of the feed of the corresponding injection device (3) is controlled to optimize the blowing off of solvent vapor by the blowing device (7) of the surface of the solvent is tracked at a defined distance. A blow-off system (100) for removing solvents from a plurality of fractionation containers (1) having a substance solution (110) and isolating a respective substance of each fractionation container (1), with a discharge device (7) for discharging a carrier gas charged with solvent vapor ( 8) from the fraction containers (1), characterized in that the blow-off system (100) has a blowing device (7) for supplying a flow of a carrier gas (8) into each fraction tank (1) and to the surface of the corresponding substance solution (110), in that the discharge device (7) has a plurality of discharge channels (71) which are designed to separate a discharge stream (710) of solvent vapor-laden carrier gas of a respective fraction container (1) separately, in that each discharge channel (71) is formed with a collecting channel (72) of the discharge device (7) for bringing the individual discharge streams (710) into a collecting stream (720) and for discharging it, in that each discharge channel (71) has or is designed as a flow barrier for preventing a backflow of the collecting stream (720) into the fractionation containers (1) and for preventing contamination of the substances to be isolated in the fractionation containers (1). 5. blow-off system (100) according to claim 4, characterized in that the injection device (3), the discharge device (7), a condensation device (9) for drying the discharged carrier gas and a conveying means (6) for conveying the carrier gas to a closed circuit are connected. 6. blow-off system (100) according to claim 5, characterized in that the discharge device (7) with the condensation device (9) is connected, each leakage (710) individually or the leakage as a collective stream (720) of the condensation device (9) can be fed , 7. blow-off system (100) according to one of claims 5 or 6, characterized in that the condensation device (9) is designed for heat recovery and for thermostating the carrier gas. 8. blow-off system (100) according to one of claims 5 to 7, characterized by a between the condensation device (9) and conveying means (6) arranged filter (90) for filtering substance particles from the carrier gas. 9. blow-off system (100) according to one of claims 4 to 8, characterized in that the blow-off system (100) has a heater (20) for supplying evaporation energy to the fractionation containers (1). 10. Blow-off system (100) according to one of claims 4 to 8, characterized in that the blow-off system (100) has a heater (19) for thermostating the carrier gas before it is fed to the fractionation containers (1). 11. Blowing system (100) according to one of claims 4 to 10, characterized in that the injection device (3) has a carrier with the number and the position of the fraction container (1) corresponding hollow needles (30). 12, blow-off system (100) according to claim 11, characterized in that the Abblassystem (100) comprises a controllable means (45) for continuously tracking the carrier with the hollow needles (30) corresponding to the decrease in the solvent level in the fractionation containers (1). 13. Blow-off system (100) according to any one of claims 11 or 12, characterized in that the carrier of the injection device (3) the number and the position of the fraction container (1) corresponding discharge pipes (31) which in the fraction container (1) insertable are. 14, blow-off system (100) according to one of claims 11 to 13, characterized in that the carrier of the injection device (3) is mechanically coupled to the discharge device or permanently connected thereto. 15. Blowing system (100) according to one of claims 4 to 14, characterized in that the carrier gas is an inert gas.