DE20300046U1 - Rotary evaporator used for automatic distillation processes has membrane pump connected to outlet of condenser on suction side and to condensate collecting vessel on pressure side, and rinsing air feed - Google Patents

Abstract

A rotary evaporator has a membrane pump connected to the outlet of a condenser on the suction side and to a condensate collecting vessel on the pressure side, and a rinsing air feed. A rotary evaporator comprises an evaporator flask (3) for a product to be evaporated; a heating bath (8) for heating the flask and the product; a motor (7) for rotating the flask in the bath; a condenser (4) for condensing the distillate into a condensate; a vacuum device for producing a vacuum in the flask and condenser; a feed unit for automatically introducing the product into the flask; a removal device for automatically removing condensate; and a process computer (10) for regulating and controlling the running of the distillation, the product feed and the condensate removal. The evaporator further comprises a membrane pump (14) connected to the outlet of the condenser on the suction side and to a condensate collecting vessel (6) on the pressure side; and a rinsing air feed (16) which can be switched using a control valve (17). The pump acts as the vacuum device. Preferred Features: The control valve opens when the suction power of the pump decreases as a result of the condensate. The low pressure prevailing in the flask and in the condenser thermodynamically matches the evaporation pressure and/or boiling point of the product.

Description

HEI 116/OG/DE

Applicant: Heidolph Instruments GmbH & Co. KG, Schwabach, DE

Rotary evaporator for automatic distillation

The invention relates to a rotary evaporator for automatic distillation. Such rotary evaporators comprise an evaporator flask for receiving a product to be evaporated, a heating bath for heating the evaporator flask and the product, a motorized rotary drive for rotating the evaporator flask in the heating bath, a cooler for condensing the distillate evaporated from the product into a condensate, a vacuum device for generating a vacuum in the evaporator flask and the cooler, a feed device for automatically feeding product into the evaporator flask, a removal device for automatically removing condensate and a process computer for regulating and controlling the distillation process, the product feed and the condensate removal.

Rotary evaporators are distillation apparatus in which a gentle and rapid distillation of a mixture of substances, which is referred to as a product, product template, sample or sample solution, is possible by means of heat, vacuum and rotation of the evaporating flask. Rotary evaporators are used in the chemical industry, biochemistry, pharmaceutical production, in

Used in laboratory applications, in crystallization, for concentrating solutions, in reflux distillation, in powder and granulate drying, in evaporating suspensions and in purifying chemicals in laboratories, in pilot plants and in industry.

Especially in the case of large rotary evaporators, i.e. systems with an evaporator flask volume of more than ten liters, it is common practice to equip the rotary evaporator with a process computer that regulates and controls the distillation process. If larger quantities of a product are to be distilled, it is usually necessary to interrupt the distillation process in order to refill the product or remove the condensate. This not only leads to a disadvantageous interruption of operation, but also requires the activity of at least one operator, which is costly and also requires a considerable amount of protection for the safe operation of the system.

For this reason, it was proposed in the generic document DE 3526644 C2 to provide a feed device for automatically feeding product into the evaporator flask and a removal device for automatically removing condensate, so that the operating sequence does not have to be interrupted and the vacuum system does not have to be ventilated in order to remove the condensate.

However, the rotary evaporator proposed in the document DE 3526644 C2 is not yet completely satisfactory in practical terms, as it requires a considerable technical effort for the removal device for the automatic removal of condensate. In addition, the system proposed in this document does not allow complete removal of the condensate, as

the condensate in the rotary evaporator also serves as a vacuum seal and therefore cannot be completely removed. Furthermore, the known device requires a very considerable amount of control and regulation effort to carry out the distillation precisely, avoiding boiling delays and to precisely maintain the desired distillation process.

Taking this state of the art into account, the invention is based on the object of creating a rotary evaporator for automatic distillation which requires little equipment, enables simple regulation and control of the distillation process and enables a fully automated distillation process including supply of product, execution of the distillation process and automatic condensate removal.

This object is achieved according to the invention by a rotary evaporator having the features of the appended claim 1. Preferred embodiments and further developments of the invention emerge from the dependent claims and the following description with associated drawings.

A rotary evaporator according to the invention for automatic distillation, comprising an evaporator flask for receiving a product to be evaporated, a heating bath for heating the evaporator flask and the product, a motorized rotary drive for rotating the evaporator flask in the heating bath, a cooler for condensing the distillate evaporated from the product into a condensate, a vacuum device for generating a vacuum in the evaporator flask and the cooler, a filling device for automatically feeding product into

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the evaporator flask, a removal device for automatically removing condensate and a process computer for regulating and controlling the distillation process, the product supply and the condensate removal, thus has the special feature that the rotary evaporator comprises a diaphragm pump which is connected on the suction side to the outlet of the cooler and on the pressure side to a condensate collecting vessel, the diaphragm pump serving as a vacuum device for generating a vacuum in the evaporator flask and the cooler and as a removal device for removing condensate, and that the rotary evaporator has a purge air supply to the suction side of the diaphragm pump which can be switched by means of a purge air control valve and which is designed as a bypass from the pressure side to the suction side of the diaphragm pump.

The use of a diaphragm pump explained above is described in the document DE 10022293 Cl, the disclosure content of which is expressly and completely referred to, for a distillation that is not carried out automatically. Within the scope of the invention, it was recognized that the method described therein and the diaphragm pump described therein can also be advantageously used in a generic rotary evaporator for automatic distillation.

The use of the diaphragm pump both for generating the vacuum in the evaporator flask and the cooler and for removing condensate not only has the advantage of reduced equipment costs, but also enables the physically determined determination of the distillation pressure as described in the document DE 100222 93 Cl without the need for very complex control and regulation devices. An appropriately equipped automatic rotary evaporator is therefore

technically uncomplicated and yet enables precise distillation with high distillation rates.

The more detailed design of the diaphragm pump and its components can be as proposed in the document DE 100222 93 Cl. In particular, according to advantageous features, it can be provided that the purge air control valve opens and closes at a predetermined cycle rate, e.g. after reaching a predetermined negative pressure, or that the purge air control valve opens when the suction power of the diaphragm pump decreases due to sucked-in condensate, whereby the negative pressure prevailing in the evaporator flask and in the cooler thermodynamically adjusts to the respective evaporation pressure or boiling point of the product, or that a further purge air control valve is arranged in the purge air supply in series with the purge air control valve, which opens and closes at a predetermined cycle rate and at a different time to the purge air control valve in order to compensate for dynamic pressure fluctuations due to backflow effects.

A rotary evaporator for automatic distillation according to the invention is a cost-effective apparatus which enables automatic supply of product, automatic distillation and automatic condensate removal without the need for operator activity or very complex control and regulation.

The invention is explained in more detail below using an embodiment shown in the figures. The special features described therein can be used individually or in combination with one another to create preferred embodiments of the invention. They show:

Fig. 1 is a simplified perspective view of a rotary evaporator according to the prior art,

Fig. 2 is a diagram illustrating a rotary evaporator according to the invention, and Fig. 3 is a modification of Fig. 2.

Figure 1 shows a rotary evaporator 1. It comprises a housing 2, a spherical evaporator flask 3, a cooler 4 and an aftercooler 5 with a condensate collection vessel 6. The evaporator flask 3 can be connected to a motorized rotary drive 7 or separated from the rotary drive 7 for handling purposes.

The evaporator flask 3 is immersed in a heating bath 8, e.g. a water or oil bath, which in the illustrated embodiment is enclosed by a housing 2 and can be moved vertically by motor or manually.

To carry out a distillation, the evaporator flask 3 is filled with the product to be evaporated and heated by the heating bath 8. The distillate is condensed in the cooler and the condensate is led through the aftercooler into the condensate collection vessel 6. The gas spaces of the evaporator flask 3, cooler 4, aftercooler 5 and condensate collection vessel 6 are connected to one another and are evacuated by a vacuum pump (not shown). A process computer 10 is provided to control the distillation process, which monitors, controls and regulates parameters such as pressure, temperature, filling quantities, etc.

The rotary evaporator 1 shown in Figure 1 is a conventional embodiment according to the state of the art without complex equipment

for carrying out automatic distillation. In rotary evaporators 1 for automatic distillation, a feed device for automatically feeding product into the evaporator flask 3 and a removal device for automatically removing condensate are additionally provided, with which product can be fed into the evaporator flask 3 and condensate can be removed from the apparatus during ongoing and continuous operation, i.e. without interrupting the vacuum in the apparatus. Such automatic feed and removal devices are described, for example, in the document DE 3526644 C2.

In rotary evaporators for automatic distillation, the process computer 10 also monitors the supply of product and the removal of condensate.

Figure 2 shows a schematic diagram of a rotary evaporator 1 according to the invention. It comprises the actual rotary evaporator unit 11 with evaporator flask 3, heating bath 8 with heating device 12, rotary drive 7 and cooler 4 with a connection for cooling water 13. The evaporator flask 3 preferably has a large volume, for example 10 or 20 liters or larger.

A special feature of the rotary evaporator 1 shown in Figure 2 for automatic distillation is the use of a diaphragm pump 14 according to the document DE 10022293 Cl, which is connected on the suction side to the outlet 15 of the cooler 4 and on the pressure side to a condensate collection vessel 6. The diaphragm pump 14 is, for example, a vacuum diaphragm pump in a four-head design with a suction capacity of 4 m ³ /h, a final pressure of 9 mbar, a connected load of 350 watts and chemically resistant equipment through parts in contact with the medium made of PTFE and PEEK.

The diaphragm pump 14 serves both to generate the vacuum in the evaporator flask 3 and cooler 4, so that no additional vacuum pump is required, and to remove condensate from the cooler 4 in the manner described in the document DE 10022293 Cl during the ongoing operation of the automatic rotary evaporator 1 or the rotary evaporator unit 11, without ventilation of the system being necessary.

The rotary evaporator 1 further comprises a purge air supply 16 to the suction side of the diaphragm pump 14, which is designed as a bypass from the pressure side to the suction side of the diaphragm pump 14 and can be switched by means of a purge air control valve 17. With the purge air supply 16, condensate and/or gas can be returned from the pressure side of the diaphragm pump 14 to the suction side of the diaphragm pump 14 as required.

The purge air control valve 17 is designed as a solenoid valve, for example. It ensures that the vacuum pump 14 is purged through the purge air line switched by it, so that the diaphragm pump 14 can also pump the condensate that accumulates.

Due to the specific design and use of a diaphragm pump 14, which simultaneously creates the vacuum and removes the condensate, a pressure is established in the evacuated system that corresponds to the boiling point of the product. Depending on the composition of the components remaining in the product, the pressure drops during distillation. The diaphragm pump 14 establishes the pressure necessary for the distillation to continue.

Further advantageous features (see also the document DE 10022293 Cl) can consist in the fact that the purge air control valve 17 opens and closes in a predetermined cycle ratio after a predetermined negative pressure has been reached or that the purge air control valve 17 opens when the suction power of the diaphragm pump 14 decreases due to sucked-in condensate, whereby the negative pressure prevailing in the evaporator flask 3 and in the cooler 4 thermodynamically adjusts to the respective evaporation pressure or boiling point of the product.

In the embodiment shown in Figure 2, the purge air supply 16 comprises a throttle element 18 for metering or reducing the purge air, for example a throttle, a nozzle or, as shown in Figure 2, an orifice plate.

Furthermore, in Figure 2, an aftercooler 19 is arranged on the pressure side of the diaphragm pump 14, the inlet of which is connected to the outlet of the diaphragm pump 14 and the outlet of which is connected to the condensate collection vessel 6. The aftercooler 19 ensures that the condensate temperature on the pressure side of the diaphragm pump 14 is reduced. According to a further advantageous feature, a separating vessel 20 for separating liquid and gaseous components of the condensate, i.e. for separating the condensate from the purge air, is connected downstream of the aftercooler 19 on the outlet side. In a preferred embodiment, the separating vessel 20 is integrated into the aftercooler 19. The purge air line on the pressure side opens into the gas space of the separating vessel 20, as shown in Figure 2.

On the suction side of the diaphragm pump 14, a check valve 21 is arranged, which ensures that the

Purge air supplied to the suction side of the diaphragm pump 14 does not enter the evacuated system.

According to a further advantageous feature, it is proposed that the rotary evaporator 1 has a weight sensor 22 for determining the amount of product in the evaporator flask 3 or the weight of the evaporator flask 3 and the product, the signal of which is fed to the process computer 10. The signal from the weight sensor 22 can be used to determine the filling amount of the evaporator flask 3 and to control the time and quantity of the product being added. The weight sensor 22 is preferably integrated into the motorized rotary drive 7.

The process computer 10 monitors, controls and regulates the distillation process, for example the temperature of the heating bath 8, the rotation speed of the evaporator flask 3, the duration of the distillation, the final pressure at which the distillation is stopped, the maximum filling of the evaporator flask 3 or the minimum filling of the evaporator flask 3. When a set final pressure value or a predetermined time is reached, the process computer 10 can automatically switch off the distillation. The final pressure value can be set by the user according to the product or on the basis of empirical values.

The diaphragm pump 14, optionally with aftercooler 19 and separator tank 20, serves as a removal device for the automatic removal of condensate. The feed device for the automatic feeding of product into the evaporator flask 3 from a product reservoir 23 is also controlled by the process computer 10 via a product feed control valve 24. According to a further advantageous feature, a product sensor 25 can be provided,

which detects the presence of product and switches off the dosing if there is no product. The product sensor 25 can be arranged in the product feed as shown in Figure 2 or alternatively directly in the product feeder 23.

In the embodiment of a rotary evaporator 1 according to the invention shown in Figure 2, the suction-side purge air line opens between the check valve 21 and the diaphragm pump 14. Figure 3 shows a modified, preferred embodiment in which, in contrast to Figure 2, the suction-side purge air line opens on the inlet side of the cooler 4, so that the cooler is arranged between the opening 9 of the purge air line and the inlet of the diaphragm pump 14. This preferred embodiment shown in Figure 3 not only has the advantage that it is operationally reliable, but moreover, as the comparison of Figure 3 with Figure 2 shows, the check valve 21 can also be omitted.

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HEI 116/OG/DE

List of reference symbols

1 rotary evaporator

2 housings

3 evaporator flasks

4 coolers

5 Aftercooler

6 Condensate collection vessel

7 Rotary drive 8 Heating bath

9 Mouth

10 process computers

11 Rotary evaporator unit

12 Heating system 13 Cooling water

14 Diaphragm pump

15 Output

16 Purge air supply

17 Purge air control valve 18 Throttle element

19 Aftercooler

20 separator tanks

21 Check valve

22 Weight sensor 23 Product template

24 Product feed control valve

25 Product sensor

Claims (15)

1. Rotary evaporator ( 1 ) for automatic distillation, comprising an evaporator flask ( 3 ) for receiving a product to be evaporated, a heating bath ( 8 ) for heating the evaporator flask ( 3 ) and the product, a motorized rotary drive ( 7 ) for rotating the evaporator flask ( 3 ) in the heating bath ( 8 ), a cooler ( 4 ) for condensing the distillate evaporated from the product into a condensate, a vacuum device for generating a vacuum in the evaporator flask ( 3 ) and the cooler ( 4 ), a feed device for automatically feeding product into the evaporator flask ( 3 ), a removal device for automatically removing condensate and a process computer ( 10 ) for regulating and controlling the distillation process, the product feed and the condensate removal, characterized in that
the rotary evaporator ( 1 ) comprises a diaphragm pump ( 14 ) which is connected on the suction side to the outlet of the cooler ( 4 ) and on the pressure side to a condensate collecting vessel ( 6 ),
wherein the diaphragm pump ( 14 ) serves as a vacuum device for generating a vacuum in the evaporator flask ( 3 ) and the cooler ( 4 ) and as a removal device for removing condensate,
and the rotary evaporator ( 1 ) has a purge air supply ( 16 ) to the suction side of the diaphragm pump ( 14 ) which can be switched by means of a purge air control valve ( 17 ) and which is designed as a bypass from the pressure side to the suction side of the diaphragm pump ( 14 ). 2. Rotary evaporator ( 1 ) according to claim 1, characterized in that the purge air control valve ( 17 ) opens and closes in a predetermined cycle ratio. 3. Rotary evaporator ( 1 ) according to one of the preceding claims, characterized in that the purge air control valve ( 17 ) opens when the suction power of the diaphragm pump ( 14 ) decreases due to sucked-in condensate, wherein the negative pressure prevailing in the evaporator flask ( 3 ) and in the cooler ( 4 ) thermodynamically adjusts to the respective evaporation pressure or boiling point of the product. 4. Rotary evaporator ( 1 ) according to one of the preceding claims, characterized in that in the purge air supply ( 16 ) in series with the purge air control valve ( 17 ) there is arranged a further purge air control valve which opens and closes with a predetermined cycle ratio and offset in time to the purge air control valve ( 17 ) in order to compensate for dynamic pressure fluctuations due to backflow effects. 5. Rotary evaporator ( 1 ) according to one of the preceding claims, characterized in that the purge air supply ( 16 ) has a throttle element ( 18 ) for metering the purge air, in particular a throttle, a nozzle or a perforated diaphragm. 6. Rotary evaporator ( 1 ) according to one of the preceding claims, characterized in that on the pressure side of the diaphragm pump ( 14 ) an aftercooler ( 19 ) is arranged, the inlet of which is connected to the outlet of the diaphragm pump ( 14 ) and the outlet of which is connected to a condensate collecting vessel ( 6 ). 7. Rotary evaporator ( 1 ) according to claim 6, characterized in that a separating vessel ( 20 ) for separating liquid and gaseous components of the condensate is connected downstream of the aftercooler ( 19 ) on the outlet side. 8. Rotary evaporator ( 1 ) according to claim 7, characterized in that the separating vessel ( 20 ) is integrated into the aftercooler ( 19 ). 9. Rotary evaporator ( 1 ) according to claim 7 or 8, characterized in that the pressure-side purge air line opens into the gas space of the separating vessel ( 20 ). 10. Rotary evaporator ( 1 ) according to one of the preceding claims, characterized in that it comprises a check valve ( 21 ) which is arranged on the suction side of the diaphragm pump ( 14 ), and the suction-side purge air line opens between the check valve ( 21 ) and the diaphragm pump ( 14 ). 11. Rotary evaporator ( 1 ) according to one of the preceding claims, characterized in that the suction-side purge air line opens onto the inlet side of the cooler ( 4 ), so that the cooler ( 4 ) is arranged between the opening ( 9 ) of the purge air line and the inlet of the diaphragm pump ( 14 ). 12. Rotary evaporator ( 1 ) according to one of the preceding claims, characterized in that it comprises a weight sensor ( 22 ) for determining the weight of the evaporator flask ( 3 ) and product and for controlling the product supply. 13. Rotary evaporator ( 1 ) according to claim 12, characterized in that the weight sensor ( 22 ) is integrated into the motorized rotary drive ( 7 ). 14. Rotary evaporator ( 1 ) according to one of the preceding claims, characterized in that it comprises a product supply control valve ( 24 ) for controlling the supply of product from a product reservoir ( 23 ) into the evaporator flask ( 3 ). 15. Rotary evaporator ( 1 ) according to one of the preceding claims, characterized in that the product reservoir ( 23 ) or the product feed comprises a product sensor ( 25 ) for detecting the presence of product in the product reservoir ( 23 ) or in the product feed.