DE102010009083A1 - Vacuum pump e.g. liquid-sealed vacuum pump, for use as rotary vane pump, has two pumping stages respectively arranged at vacuum side and pressure side, where one of pumping stages is implemented as screw pumping stage with screw pump unit - Google Patents

Abstract

The pump has two pumping stages (1, 2) arranged at a vacuum side and a pressure side, respectively. One of the pumping stages is implemented as a membrane pumping stage with a membrane pump unit (10). The pumping stage is dimensioned such that the pumping stage provides 20 percentage of pumping speed to the pump at atmospheric pressure. The other pumping stage is implemented as a screw pumping stage with a screw pump unit (5). A pair of screw-shaped rotors (7a, 7b) is supported at the screw pump unit. The pumping stage is implemented as the screw pumping stage whose medium-contact surfaces are made of chemically persistent fluoroplastics or metal coated with fluoroplastics or ceramics.

Description

The invention relates to an oil-free and contactless running in the pump chamber vacuum pump with a final vacuum in the range 10 ² Pa to 10 ^-2 Pa (fine vacuum range) having the features of the preamble of claim 1.

Numerous processes in research and industry require a vacuum in the range 10 ² Pa to 10 ^-2 Pa, which often also condensing and / or aggressive steam or gases must be promoted. To create a vacuum in this area, liquid-sealed or lubricated vacuum pumps such as oil-sealed rotary vane pumps are often used. The use of such pumps, in which the pumped medium comes into contact with oil or other liquids, has numerous disadvantages. Thus, the pumped media can contaminate or react with the lubricant, which reduces the lubricity and sealing effect. Backflow of gaseous components or decomposition products of the lubricant in the process plant can interfere with the local processes sensitive.

For this reason, so-called "dry" vacuum pumps, ie pumps in which the pumped media does not come into contact with liquid, have long been appreciated.

At higher pressures, ie in the range of 10 ⁵ Pa to 10 ² Pa, diaphragm vacuum pumps ( DE-C-199 04 350 ) Advantageous, since there the pumping chamber is hermetically separated by a gas-tight membrane clamped from the drive range and - for chemical applications - the wetted parts of the pump can be made of chemically resistant materials such as fluoroplastics. Diaphragm vacuum pumps are very popular for both chemical and non-chemical applications because they are reliable, robust and can be produced inexpensively even for small pumping speeds in the range of 1 to 15 m ³ / h, for example for laboratory applications. However, due to a limited compression ratio and the valves which are usually actuated only by the gas flow, pressures below 50 Pa are difficult to achieve. This vacuum is not sufficient for applications requiring fine vacuum.

Piston pumps reach final pressures in a fine vacuum up to 1 Pa due to their higher compression ratio and the simple possibility to control the gas inlet and outlet by the piston itself. However, the piston seal is a sliding seal. Such seals have a comparatively high leakage rate, i. H. the pump chamber is not hermetically separated from the drive compartment (with, for example, grease-lubricated bearings). This can cause contamination of the pumped media by oils or greases, as well as corrosion in the drive compartment due to aggressive pumped media. In addition, these seals are sensitive to condensates and particles. In addition, piston seals are difficult to produce with the required precision and have only a limited life.

Another common type of fine vacuum pumps are scroll pumps. These are based on the conveyance of the medium in crescent-shaped volumes, which are formed by a cross-sectionally helical, axially parallel rotor in engagement with a similar spiral-shaped stator. The movable scroll is placed in an orbital motion by an eccentric drive and a mechanism that prevents the spiral from rotating.

The disadvantage is that in order to achieve the desired vacuum data grinding seals on the faces of the spirals are necessary. These seals are sensitive to condensates and particles and have a limited life. In addition, abrasion from the abrasive seals in the form of dust is observed in the pump chamber after some operating time, which can interfere with both the function of the pump itself and connected processes. This disadvantage can be avoided by the combination of a scroll pump with a diaphragm pump as forepump ( DE-A-102 25 774 ; DE-A-10 2005 042 451 ). However, the known arrangements are comparatively expensive.

Another common type of fine vacuum pumps is based on Roots pumps, also called Roots pumps. Two 8-shaped pistons roll without contact, d. H. without abrasive seals, as in a piston or scroll pump, in a suitably shaped housing, synchronously abutted together, thereby delivering gas from the inlet to the outlet. With such an arrangement, compression ratios of about 10-30 can be achieved. For the fine vacuum generation, therefore, a forepump or a multi-stage construction is also required here. A disadvantage is the complex structure of such multi-stage arrangements and the tight mechanical tolerances that must be adhered to during manufacture and operation. In addition, such arrangements are sensitive to condensates, aggressive media or particles.

The same applies to claw pumps ( GB 429,171 ), which, however, can achieve a compression ratio of about 50, so get along with a smaller number of stages as Roots pumps. Claw pumps also have two non-contact synchronously running rotors on. They are especially popular for larger pumping speeds (> 50 m ³ / h). For smaller pumping speeds, the requirements for the gap dimensions are too high for an economic realization. This is because as the size of the rotors decreases, the relative backflow losses through the gaps between the rotors and between the rotors and the housing become larger and larger. At the same time, these gaps can not be reduced arbitrarily, on the one hand because of manufacturing limitations, on the other hand because of the material expansion by - just at compression to atmospheric pressure - inevitable increase in temperature due to the compression of the gases. This means that a claw pump with <50 m ³ / h maximum pumping speed would be less compact and cheaper to produce than a much larger.

In order to reduce disturbing heating, in particular when pumping off gases with low thermal conductivity, it is known to combine a root pump or a claw pump with an auxiliary pump ( EP-A-1 243 795 ).

Another common type of fine vacuum pumps are screw pumps ( DE-C-594 691 ). In screw pumps, two helical rotors abut each other in a suitably shaped housing forming the pumping chamber, thereby delivering gas from the inlet to the outlet. The rotors are driven by two synchronously running motors ( DE-A-195 22 560 ) or by means for driving and synchronizing the rotors from a single drive shaft.

Screw pumps are especially popular for higher pumping speeds (> 100 m ³ / h). For smaller pumping speeds or sizes, the requirements for the gap dimensions are too high for economical implementation, for reasons similar to those of claw pumps. The advantage of screw pumps in comparison to roots or claw pumps is the high possible compression, since screw pumps can be built up intrinsically in many stages, with each screw thread acting as a step. Screw pumps thus offer the possibility of achieving a deep end vacuum with only one pair of rotors. With only one rotor pair, a so-called flying bearing of this pair of rotors is possible. Ie. the rotors are mounted only on one side, which is a simple disassembly of the stator (housing part) z. B. allowed for maintenance and cleaning purposes.

As mentioned above, claw and screw pumps are presently offered only for greater pumping speeds (> 50 m ³ / h), since with smaller pumps the relative backflow losses and also the thermal problems with compression to atmospheric pressure with the associated material expansion for an economical realization grow up.

For smaller pumping speeds (<50 m ³ / h), scroll pumps, piston pumps and multistage roots pumps are available for oil-free fine vacuum generation, with the disadvantages described above.

The object of the present invention is to specify a vacuum pump operating in the suction chamber dry and without sliding seals for the range up to a fine vacuum with a pumping rate <50 m ³ / h. Preferably, the vacuum pump should also be compact and economical to manufacture and operate.

The above object is achieved in a two-stage vacuum pump having the features of the preamble of claim 1 by the feature of the characterizing part of claim 1. According to the invention, in the two-stage pump, the first pump stage is a screw pump stage, while the second pump stage, which is arranged on the pressure side, a diaphragm pumping stage. The diaphragm pump stage is dimensioned relative to the screw pump stage so that it provides at least 20% of the pumping speed of the vacuum pump at atmospheric pressure (normal conditions). It should therefore be an effective unit as an independent pumping unit. Preferably, the membrane pumping stage should be able to provide up to 50% of the vacuum pump's vacuum capacity at atmospheric pressure (normal conditions).

Due to the diaphragm pump stage arranged on the pressure side, this acts as an effective backing pump for the screw pump stage. This brings several advantages. The compression of the gases and vapors to atmospheric pressure does not occur within the screw pumping stage, but within the membrane pumping stage, thereby avoiding excessive release of heat of compression and thus temperature increase within the screw pumping stage. In addition, when condensable vapors are pumped, condensation may not occur in the more sensitive screw pumping stage but in the more robust diaphragm pumping stage. Also, the deposition of solids from pumped media within the screw pumping stage is reduced.

The screw pumping stage must compress at low pressures only to the final vacuum of the membrane pumping stage, which is in the order of 50 to 10 ³ Pa. At these low pressures, backflow effects through the gaps between the rotors as well as between the housing wall and the rotors are already significantly reduced. This allows the Design of the rotors with relatively larger columns, which has a positive effect on the manufacturability of the components, their cost, and on the requirements of the thermal or cooling.

With a final vacuum of <1 Pa and a pre-vacuum of 50 to 10 ³ Pa provided by the membrane pumping stage, the screw pumping stage need only provide a compression of about 50-1000 instead of full compression to atmospheric pressure (> 10 ⁵ ). As a result, fewer "stages", ie screw flights, than without a backing pump are sufficient for the more expensive screw pumping stage compared to a diaphragm pumping stage.

If one starts from a diaphragm pumping stage with a good ultimate vacuum <100 Pa, one comes with a surprisingly small number of screw threads in the screw pump stage to achieve the desired final vacuum in the fine vacuum range. So you can run the helical rotors of the screw pump unit so short that they can fly with little effort flying (one-sided storage). This has a significant advantage - not only for assembly and disassembly - but also for cleaning and repair purposes (see, for example DE-A-195 22 560 ).

The preferred embodiment with overhung helical rotors is particularly advantageous for applications with condensing vapors or aggressive gases.

For such applications, the membrane pumping stage is preferably designed as a chemical membrane pumping stage in which the wetted surfaces are made of chemically resistant materials such as fluoroplastics or perfluoroelastomers, or lower requirements of appropriately sized materials.

For the screw pumping stage, it is also advisable under these boundary conditions that their wetted surfaces consist at least in part of highly resistant fluoroplastics, such as PTFE, ETFE, ECTFE, PFA, preferably reinforced by fillers such as carbon particles, carbon fibers or other synthetic fibers. Alternatively, other chemically resistant, also preferably reinforced plastics such as PEEK, PPS, PP or PE come into question.

Another alternative is ceramic materials or metals with chemically resistant coating of the above-mentioned plastics. Such materials generally have a poorer thermal conductivity and sometimes also significantly higher thermal expansion coefficients than conventional metallic materials such as aluminum, which are mostly used for non-chemical applications.

The use of chemically resistant materials for the screw pump stage is greatly facilitated, if not made possible, by the backing pump with its positive effects on the allowable gap dimensions and the thermal conditions in the screw pump stage.

For applications with condensing media, the vacuum pump according to the invention is preferably designed so that the outlet of the screw pumping stage is mounted at the lowest point or near the lowest point, so that condensates can be easily conveyed out of the pump chamber of the screw pumping or screw pump unit.

For applications with condensing or aggressive media vacuum pump according to the invention is preferably designed so that not only the diaphragm pumping a gas ballast, ie an inlet for a purge gas, in particular air, but also the screw pumping stage, wherein the addition of purge gas in the screw pumping stage preferably either takes place at the inlet or in the vicinity of the shaft seal.

In a preferred embodiment, the drive motor of the screw pumping stage and / or the drive motor of the diaphragm pumping stage is variable in speed. A further increase in the flexibility and the performance of the vacuum pump according to the invention with simultaneously high compactness is achieved by the design of the drive unit with electronically commutated DC motors. Such drive motors are compact, powerful and speed controllable. This makes it possible to operate at high suction pressures the drive motor of the diaphragm pumping stage at high speed in order to achieve a high pumping speed in this pressure range. The screw pumping stage operates in this pressure range due to the low "sealing effect" of the column basically inefficient, ie the pumping speed is determined by the diaphragm pumping stage. At lower pressures, the speed of the drive motor of the diaphragm pump stage can be reduced while the speed of the screw pump stage drive motor is increased. This results in a full exploitation of the efficiency of the screw pumping stage in this pressure range and the accessibility of a very deep final vacuum. At the same time, membrane life is prolonged by the reduced speed of the membrane pump stage drive motor, as in many applications, after a short pump down cycle, long operation follows at low pressures. At high intake pressures, a large proportion of the total output goes in the drive of the diaphragm pumping stage, at low intake pressures, however, in the drive of the screw pumping stage. This leads to a comparatively constant average power requirement at the DC power supply unit. For pressure or process-dependent control of the drive units, a correspondingly programmable controller can be provided.

In another preferred embodiment, the diaphragm and the screw pump stage are driven by a common drive motor, wherein in a further preferred embodiment between the diaphragm and the screw pumping stage, there is a speed difference, the screw pump stage preferably runs at a higher speed. The power transmission means with the ability to change the speed between the diaphragm and screw pumping stage can be for example a gear, a toothed belt, a chain or a toothed chain. Preferably, this means for speed change is integrated in the means for driving and speed synchronization of the two rotors.

In another embodiment with a common drive motor and speed difference between screw and diaphragm pumping stages, the power transmission means has a variable ratio, so that, for example, at high suction pressures the screw pumping stage can run slower to avoid overloading the screw pumping stage or the drive motor, and only at low Suction pressure, the screw pump stage runs at full speed. The speed control may also be by other parameters than the suction pressure, such as the engine load (motor current), the time or the temperature of the screw pumping stage, or by an external control signal, for example from a process control. Of course, this also applies to the other disclosed variable-speed drive versions.

As mentioned above, maximum pumping speeds of 1 to 15 m ³ / h are common in membrane vacuum pumps. To increase the maximum pumping speed of the vacuum pump according to the invention - without significant additional costs - it is advisable to combine a diaphragm pumping stage preferably with a slightly larger screw pumping stage. Typically, the screw pumping stage will be designed to be 1 to 5 times the maximum pumping capacity of the membrane pumping stage.

With more than 1.5 times the pumping speed of the screw pumping stage, a pressure relief valve with bypass line is preferably provided between the screw and the diaphragm pumping stage around the diaphragm pumping stage so as not to load the screw pumping stage at high pressure at its outlet.

In another embodiment, the inlet / gas inlet of the screw pumping stage is connected to the inlet / gas inlet of the membrane pumping stage by means of a bypass arrangement with a bypass line and with a valve arrangement such that at high suction pressures the inlet of the screw pumping stage is closed and the medium to be delivered directly from the membrane pumping stage is encouraged. As a result, the load of the screw pumping stage with possibly condensing or aggressive media is further reduced, without the pumping speed of the overall arrangement is significantly adversely affected at high pressures. At low suction pressures, preferably <5 × 10 ⁴ Pa, the bypass line is closed and the gas precompressed by the screw pumping stage before it enters the diaphragm pumping stage. Thus, the suction capacity at <5 × 10 ⁴ Pa and the final vacuum remains unaffected compared to the arrangement without bypass line. In a further embodiment, not only the inlet, but the inlet and the outlet of the screw pumping stage is closed at high suction pressures in order to prevent ingress of gases from the outlet side into the screw pumping stage.

In a preferred embodiment of the above arrangement, the inlet / gas inlet of the screw pumping stage is not closed at high pressures, but opened to the atmosphere or to a purge gas via a reduced cross-section nozzle to purge the pumping chamber suction space and any previous liquid or solid residues Expel pumping operations. The nozzle of reduced cross-section compared to the intake manifold causes typically no more than 10% of the pumping rate to be supplied to the membrane pumping stage in the form of purge gas. The pumping speed available for the application of the diaphragm pumping stage is therefore only marginally reduced. The outlet / gas outlet of the screw pump stage must remain open in this case.

The sealing of the pump chamber of the screw pump stage on the waves against the atmosphere is preferably carried out with shaft seals, which are preferably dry-running, so without lubricant, are formed. Possible suitable material combinations for such dry-running sealing rings are, for example, PTFE on hardened, optionally polished steel or PTFE on diamond-like carbon layers or other coatings.

In a further preferred embodiment, the shaft seals are arranged in pairs one behind the other, wherein preferably between the shaft seals an intermediate vacuum is applied, which is provided for example by connection to one of the stages of - usually multi-stage - diaphragm pumping stage.

In another embodiment, the sealing of the pump chamber of the screw pumping stage takes place on the waves against atmosphere through narrow gaps or a so-called labyrinth seal. This is an arrangement with narrow gaps, in which the leak rate through the column is sufficiently small.

In the following the invention will be explained with reference to an exemplary embodiments illustrative drawing. In the drawing shows

1 a schematic representation of a two-stage vacuum pump according to the invention with separate drive motors,

2 a second embodiment similar 1 but with a common drive motor,

3 similar to another embodiment 2 provided with a bypass arrangement and

4 in an enlarged view, also schematically simplified, a particular embodiment of a shaft seal for a helical rotor of a vacuum pump according to the invention.

The invention relates to a vacuum pump with two pump stages of different configuration, wherein each of the two pump stages may in turn have more than one pump unit.

Which shows a first embodiment 1 shows a schematic representation of a vacuum pump according to the invention. This consists of the combination of a first, arranged on the vacuum side, so a recipient pumping stage facing 1 , shown here as a screw pumping stage 1 , which in turn may consist of several screw pumping units, as well as a second, arranged on the pressure side, so the ambient atmosphere facing pumping stage 2 , here in the form of a diaphragm pumping stage 2 , which can consist of several membrane pump units. The screw pumping stage 1 has a drive motor 3 , z. B. an electric motor, a power transmission means 4 for storage, drive and synchronization and the actual screw pump unit 5 consisting of a stator 6 and two intermeshing helical rotors 7a and 7b on. Gas enters the gas inlet 8th A, is due to the rotation of the two helical rotors 7a . 7b in the stator 6 compressed and occurs at the gas outlet 9 out.

The pre-compressed gas emerges from the gas outlet 9 in the membrane pumping stage 2 a, which at least one membrane pump unit 10 and a drive motor 11 , such as an electric motor. The compressed to atmospheric pressure gas occurs at the gas outlet 12 out.

Which shows a further embodiment 2 shows a schematic representation of a vacuum pump according to the invention with a common drive motor 3 and an external bypass line 13 to bypass the diaphragm pump unit 10 , The vacuum pump in turn consists of the combination of a screw pumping stage 1 with a diaphragm pumping stage 2 , The complete vacuum pump is powered by a common drive motor 3 driven, wherein in this particular embodiment, the drive power z. B. by means of a continuous rotating shaft through the membrane pump unit 10 in the power transmission means 4 is transmitted. The power transmission means 4 serves in this case both for storage, drive and synchronization of the two rotors 7a . 7b , as well as for power transmission from the diaphragm pump unit 10 on the screw pump unit 5 , The power transmission means 4 could here, as in the above case, for power transmission and synchronization of the rotors 7a . 7b For example, a transmission, a toothed belt, a chain or a tooth chain contain.

The actual screw pump unit 5 consists of the stator 6 and the two paired helical rotors 7a . 7b , The gas enters the gas inlet from the recipient 8th in the screw pumping stage 1 or the screw pump unit 5 one and is due to the rotation of the two helical rotors 7a . 7b in the pump chamber inside the stator 6 compacted. The gas occurs at the gas outlet 9 from the screw pumping stage 1 out and into the membrane pumping stage 2 one. The gas outlet 9 is thus at the same gas inlet of the diaphragm pump unit 10 the diaphragm pumping stage 2 , In the diaphragm pump unit 10 the gas is compressed to atmospheric pressure and occurs at the gas outlet 12 into the atmosphere, the outside space, out.

Unlike in 1 is in the embodiment in 2 a bypass line 13 with an integrated overpressure prevention device, namely a check valve 14 , intended. The bypass line 13 leads from the connection between the two pumping stages 1 . 2 at the gas outlet 9 to the gas outlet 12 the diaphragm pump unit 10 , With activated bypass line 13 becomes the diaphragm pump unit 10 so bypassed.

In case of overpressure at the gas outlet 9 the screw pumping stage 1 opens the check valve 14 and thus prevents overloading of the screw pumping stage 1 , The bypass arrangement 13 . 14 is preferred for designs with a higher pumping pump stage pumping speed 1 when that of the membrane pumping stage 2 used and is of course applicable to embodiments with separate drive motors.

Which shows a further embodiment 3 shows a schematic representation of the vacuum pump according to the invention with a common drive motor 3 as well as external bypass line 16 at the screw pumping stage 1 , The vacuum pump in turn consists of the combination of a screw pumping stage 1 with a diaphragm pumping stage 2 , The complete vacuum pump is powered by a common drive motor 3 driven, wherein in this particular embodiment, the drive power z. B. in the form of a rotating shaft through the membrane pump unit 10 through into the power transmission means 4 is transmitted. The power transmission means 4 serves in this case for storage, drive and synchronization of the two rotors 7a . 7b and for power transmission from the drive motor 3 or membrane pump unit 10 on the screw pumping stage 1 , The power transmission means 4 could also here for power transmission and synchronization of the rotors 7a . 7b For example, a transmission, a toothed belt, a chain or a tooth chain contain.

The construction of the screw pump unit 5 is the same as in the above-discussed embodiment, so that reference may be made to the statements there.

Unlike in the first and in the second embodiment is here at the gas inlet 8th the screw pumping stage 1 a valve 15 arranged, which is designed as a shut-off valve. From the gas inlet 8th branches a bypass line 16 off, through another valve 17 can be controlled on and off. The bypass line 16 flows into the connection of the two pumping stages 1 . 2 at the gas outlet 9 the screw pumping stage 1 , In this embodiment, according to the preferred teaching also at the gas outlet 9 the screw pumping stage 1 another shut-off valve 18 intended.

The valves 15 . 17 and 18 are controlled by a suitable controller (not shown) process, time and / or pressure-dependent. A typical Abpumpvorgang could be such that when pumping of atmospheric pressure valves first 15 and 18 are closed and valve 17 is open. The gas thus flows through the bypass line 16 directly into the inlet of the membrane pumping stage 2 , As soon as, for example, the pressure in the process has been lowered sufficiently, the valves become 15 and 18 opened and valve 17 closed. Now, the further pumping out as usual by the screw pumping stage 1 ,

Alternatively, it is also possible on the valve 18 to renounce. In this case, there is also an additional gas inlet into the screw pump stage 1 for flushing the same with the valve closed 15 possible. The latter variant is not shown in the drawing, but easy to understand from the description.

A combination of the various bypass arrangements and the various drive arrangements is possible according to the invention.

4 shows a schematic representation of a shaft seal on one of the rotors 7 the screw pumping stage 1 , in the embodiment with two shaft sealing rings 21 . 22 with intermediate vacuum. Shown is a rotor 7 with a wave approach 20 , The second rotor, the bearing and the stator and all other irrelevant components are not shown for simplicity. The sealing of the suction space on the shaft 20 against atmosphere takes place here by two successively connected sealing rings 21 and 22 in a housing 23 to sit. Between the sealing rings 21 . 22 will have an opening 24 an intermediate vacuum applied by the opening 24 over a line 25 with the inlet of one of the stages of the preferred multi-stage diaphragm pumping stage 2 (not shown here) Connected. As a result, in practice, a stepwise increase of the pressure from vacuum to atmosphere via the sealing rings takes place 21 . 22 , resulting in better sealing and longer life of the sealing rings 21 . 22 contributes.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 19904350 C [0004]
• DE 10225774 A [0007]
• DE 102005042451 A [0007]
• GB 429171 [0009]
• EP 1243795A [0010]
• DE 594691 C [0011]
• DE 19522560 A [0011, 0020]

Claims (10)

Vacuum pump with a first pumping stage ( 1 ) and a second pumping stage ( 2 ), whereby the two pump stages ( 1 . 2 ) are connected in series and the first pumping stage ( 1 ) vacuum side and the second pumping stage ( 2 ) is arranged on the pressure side and wherein the second pumping stage ( 2 ) as a membrane pumping stage with at least one membrane pump unit ( 10 ) and dimensioned so that the second pumping stage ( 2 ) provides at least 20% of the suction capacity of the vacuum pump at atmospheric pressure (normal conditions), characterized in that the first pump stage ( 1 ) as a screw pumping stage with at least one screw pump unit ( 5 ), wherein, preferably, the screw pump unit ( 5 ) a pair of helical rotors ( 7a . 7b ), which are mounted only on one side. Vacuum pump according to Claim 1, characterized in that all surfaces of the vacuum pump which come into contact with the medium have a high chemical resistance to aggressive pumped media, wherein, preferably, the membrane pump stage ( 2 ) is designed as a chemical membrane pumping stage, and / or wherein, preferably, the media-contacting surfaces of the screw pumping stage ( 1 ) consist at least partially of chemically resistant fluoroplastics or other chemically resistant plastics or metal with chemically resistant coating of such plastics or ceramic or combinations of these materials. Vacuum pump according to one of the preceding claims, characterized in that, when the vacuum pump is ready for operation, the screw pump unit ( 5 ) is arranged so that its gas outlet ( 9 ) at or near the lowest point of a housing ( 6 ) and / or that the screw pumping stage ( 1 ) has an inlet for a purge gas, in particular air, wherein the addition of purge gas in the screw pumping stage ( 1 ) preferably either at the gas inlet ( 8th ) or in the vicinity of the shaft seal, in the case of a shaft seal without sealing ring (-e) is preferably carried out on the atmosphere side of the shaft seal. Vacuum pump according to one of the preceding claims, characterized in that the screw pumping stage ( 1 ) and the membrane pumping stage ( 2 ) each have their own drive unit ( 3 . 4 ; 11 ) with a drive motor ( 3 ), preferably designed as an electronically commutated DC motor, and optionally with a power transmission means ( 4 ) to the speed change that the two drive units ( 3 . 4 ; 11 ) are mechanically independent of each other and that at least one of the two drive units ( 3 . 4 ; 11 ) is designed variable in number of revolutions, wherein, preferably, a programmable controller is provided and the speed of screw pumping stage via the controller ( 1 ) and membrane pumping stage ( 2 ) is adjustable such that, depending on various process parameters, in particular the suction pressure and / or the time and / or the pressure between the pumping stages ( 1 . 2 ), an optimal pumping speed or an optimal final vacuum with optimum power consumption is achieved. Vacuum pump according to one of claims 1 to 3, characterized in that the screw pumping stage ( 1 ) and the membrane pumping stage ( 2 ) from a common drive unit ( 3 . 4 ) with only one drive motor ( 3 ), preferably embodied as an electronically commutated DC motor, are driven, wherein, preferably, between the common drive unit ( 3 ) and at least one of the pump stages ( 1 . 2 ) a power transmission means ( 4 ) is provided for speed change, so that the screw pumping stage ( 1 ) and the membrane pumping stage ( 2 ) are operable at different speeds, and / or wherein, preferably, the drive unit ( 3 . 4 ) is variable in speed and / or the power transmission means ( 4 ) has a variable translation. Vacuum pump according to one of the preceding claims, characterized in that the screw pumping stage ( 1 ) a higher nominal absorbency than the membrane pumping stage ( 2 ), that between the outlet of the screw pumping stage ( 1 ) and the inlet of the membrane pumping stage ( 2 ) a device for preventing overpressure ( 14 ) is arranged and that at a certain overpressure in the connection between the outlet of the screw pump stage ( 1 ) and the inlet of the membrane pumping stage ( 2 ) the device ( 14 ) the outlet of the screw pumping stage ( 1 ) with the outside space or with the gas outlet ( 12 ) of the membrane pumping stage ( 2 ) connects. Vacuum pump according to one of the preceding claims, characterized in that a bypass arrangement ( 15 - 18 ) is provided and that via the bypass arrangement ( 15 - 18 ) the gas inlet ( 8th ) of the screw pumping stage ( 1 ) with the gas inlet ( 9 ) of the membrane pumping stage ( 2 ) is connectable, so that at high intake pressure, the pumped gas via the bypass arrangement ( 15 - 18 ) at the screw pump stage ( 1 ) passing directly from the diaphragm pump stage ( 2 ), wherein, preferably, the bypass arrangement ( 15 - 18 ) a preferably controllable valve arrangement ( 15 . 17 . 18 ), by which the bypass arrangement ( 15 - 18 ), wherein, more preferably, the bypass arrangement ( 15 - 18 ) a controller for controlling the valve arrangement ( 15 . 17 . 18 ) having. Vacuum pump according to claim 7, characterized in that the bypass arrangement ( 15 - 18 ) is configured such that the gas inlet ( 8th ) of the screw pumping stage ( 1 ) when the bypass arrangement is activated ( 15 - 18 ) is opened via a nozzle with a small cross section to the outside or to a purge gas connection. Vacuum pump according to one of the preceding claims, characterized in that the sealing of the suction chamber of the screw pump unit ( 5 ) on the waves ( 20 ) of the helical rotors ( 7 ) against the atmosphere with one or more shaft seals ( 21 . 22 ), wherein these are preferably dry-running, ie without lubricant, are formed, wherein, preferably, on at least one shaft ( 20 ) of the screw pump unit ( 5 ) at least two shaft seals ( 21 . 22 ) are mounted one behind the other, wherein preferably between at least one pair of shaft sealing rings ( 21 . 22 ), a negative pressure is generated whose pressure value between the pressure value at the gas outlet ( 9 ) of the screw pumping stage ( 1 ) and atmospheric pressure, and where, preferably, this negative pressure from the membrane pumping stage ( 2 ) is produced. Vacuum pump according to one of claims 1 to 9, characterized in that the sealing of the suction chamber of the screw pump unit ( 5 ) on the waves ( 20 ) against atmosphere without shaft seals ( 20 . 21 ), only via gap seals.

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