EP2209995A1

EP2209995A1 - Multi-stage pump rotor for turbo-molecular pump

Info

Publication number: EP2209995A1
Application number: EP08804453A
Authority: EP
Inventors: Heinrich Engländer
Original assignee: Oerlikon Leybold Vacuum GmbH
Current assignee: Leybold GmbH
Priority date: 2007-10-11
Filing date: 2008-09-19
Publication date: 2010-07-28
Anticipated expiration: 2028-09-19
Also published as: JP5674468B2; EP2209995B1; WO2009049988A1; TW200925431A; DE102007048703A1; CN101828040B; CN101828040A; US8562293B2; US20100290915A1; JP2011501010A; TWI453345B

Abstract

The invention relates to a multi-stage pump rotor (10) for a turbo molecular pump. The pump rotor (10) has at least two separate blade disk rings (17), each having a rotor ring (12) and at least one blade disk (14). A cylindrical reinforcement pipe (18), which surrounds the rotor rings (12) of the blade disk rings (17) on the outside without clearance, is provided between the blade disks (14) of adjacent blade disk rings (17). The reinforcement pipe (18) absorbs a large part of the tangential forces occurring during operation such that the pump rotor (10) has improved stability at high rotor speeds.

Description

Multi-stage turbomolecular pump pump rotor

The invention relates to a multi-stage pump rotor of a turbomolecular pump.

Prior art turbomolecular pumps operate at speeds of several tens of thousands of revolutions per minute. The kinetic energy of a pump rotor operated at such a nominal speed is, in the case of larger turbomolecular pumps, within the range of the kinetic energy of a small car at a speed of 50-70 km / h. In the case of a rotor burst, this high kinetic energy of the rotor constitutes a high potential for destruction and injury, which can only be controlled with great effort for the mechanical shielding of the rotor. 9 _

Particularly problematic with regard to their bursting capacity are cantilevered turbomolecular pump pump rotors which are magnetically supported. In the case of magnetically mounted pump rotors which are cantilevered, it is endeavored to arrange at least one radial bearing and the drive motor in the region of the center of gravity of the pump rotor. For this purpose, it is necessary that the pump rotor is bell-shaped to accommodate the Nagnetlagerung and possibly also the drive motor in the bell cavity within the pump rotor. The bell-shaped construction of the pump rotor results in a design-related mechanical weakening of the rotor. In the usually one-piece turbomolecular pump pump rotors can be countered only by the use of high-strength aluminum alloys, which are extremely expensive because of this design-induced weakening.

The object of the invention is to provide a multi-stage turbomolecular pump pump rotor having improved strength.

The pump rotor according to the invention is no longer in one piece and has at least two separate wing disk rings, each having a rotor ring and at least one wing disk. The ends of the two rotor rings of adjacent wing disc rings are on the outside without play by a cylindrical Armierungsrohr, which is arranged between the adjacent wing discs of the adjacent rotor discs rings. The reinforcing tube is not necessarily the axial and radial fixation of the two rotor rings to each other, but it includes the two rotor rings so tightly that it receives at least a portion of the centrifugal forces in the rotor ring resulting tangential forces and mechanically relieved the rotor rings in this way.

The pump rotor is no longer one piece, but designed in several pieces. The pump rotor can be formed from a plurality of rotor rings, each with a single wing disc. Even if a rotor ring by high Centrifugal forces should break tangentially, this fraction remains locally limited to the respective rotor ring and can not readily extend to the entire pump rotor.

The axial denomination of the pump rotor and the use of a Tangentialkräfte receiving armor tube comprising the rotor rings, on the one hand the risk of pump rotor burst is significantly reduced and on the other hand, in the case of a burst of a rotor ring, the associated destruction forces and the resulting dangers Significantly reduced for man and machine.

By using several rotor rings and the reinforcing tubes, the respective components are specialized for their function. This makes it possible to optimize both the rotor ring and the reinforcing tube in terms of their function, namely the holding of the rotor blades on the one hand and the inclusion of the tangential forces on the other. The rotor ring may for example consist of inexpensive and average tensile aluminum alloys or other materials. For the reinforcing tube, however, a material is selected that can absorb high tensile forces.

As experiments and calculations have shown with one-piece pump rotors, the centrifugal load in the rotor blades is not the speed limiting factor, even in large turbomolecular pumps. The wings themselves thus allow a higher speed. In a burst of the bell-shaped pump rotor, the cracks extend substantially in the axial direction, so that arise in this way larger rotor pieces. The entire rotational energy of the rotor is then released in a bullet-like manner in a very short time.

In a burst of a single wing disc ring of a multi-piece rotor, the resulting projectile is considerably smaller and the rotor is through decelerates the contact of the relevant flyover ring with the stator much slower than a burst of a one-piece pump rotor.

Due to the formation of the pump rotor from individual Fiügeischeibenringen rings from a production point of view, the wing disk or the rotor blades can be made easier, or take more complex forms. This can lead to an improvement in the fluid mechanics in the pump stages at higher pressures within the turbomolecular pump receiving the pump rotor.

By using a lighter material for the arm tube, the total weight of the pump rotor can be reduced.

The wing disc ring can each, but need not, be integrally formed. The wing disc ring may alternatively be composed of several segments. In the division of the rotor ring into several segments occur in the rotor ring virtually no tangential forces and these are introduced exclusively in the reinforcing tube.

Preferably, the Fiügelscheibenring is formed but eänstückig. The closed one-piece wing disc ring is easier to produce and assemble.

Preferably, the Armierungsrohr material is different from the material of the wing disc rings. As a material for the reinforcing tube CFRP, so carbon fiber reinforced plastic is preferably used, which is particularly suitable because of its ability to absorb high tensile forces and because of its low weight as a material for the reinforcing tube.

According to a preferred embodiment, at least one Rotorfiügelscheibe on a single wing disk of rotor blades. The Limiting the rotor ring or rings to a single wing disc makes it possible to arrange a reinforcing tube between each wing wing pair of adjacent wing discs. As a result, a maximum of strength of the pump rotor with respect to the tangential forces is achieved. However, not all of the impeller disk rings of the pump rotor necessarily have only a single disk disk. Thus, for example, in the region of the pump rotor, in which particularly high tangential forces occur, wing disc rings are provided with a single wing disc, while in other axial areas of the pump rotor, where lower tagentiate forces occur or in which the rotor ring can be built radially stronger in that the wing disc ring concerned may also have two or more wing discs.

Preferably, the wing disc rings are clamped axially axially between two rotor shaft clamping bodies. The rotor rings may, for example, be self-centering with corresponding axial annular grooves and annular lands and be clamped together axially by the two rotor shaft clamping bodies. Alternatively or additionally, at least one rotor support body may be provided, onto which the rotor rings of the wing disk rings are pushed. The rotor support body may form the clamping body, but the clamping body but may also be formed separately from the rotor bearing bearing rotor support kör pern.

The rotor support body may be made of a different material than the rotor rings or the reinforcing tubes.

Preferably, the pump rotor has a cavity for receiving a rotor bearing, which is preferably a magnetic bearing. As has already been described in detail above, with centrifugal and magnetically levitated turbomolecular pump pump rotors, it is desired to arrange a radial bearing and the drive motor in the vicinity of the pump rotor center of gravity. Therefor a corresponding cavity in the pump rotor is uneriässiich, thereby receives a bell-shaped form. Especially in magnetgeiagerten pump rotors of turbomolecular pumps, the axial denomination of the pump rotor in individual rotor rings is particularly advantageous because in particular the cavity portion of the pump rotor is exposed due to the limitation of the pump rotor space high tangential loads.

In the following two Ausführungsbeispieie the invention are explained in detail with reference to the drawings. Show it:

Fig. 1 shows a first Ausführungsbeϊspiel a multi-stage

Turbomobility pump pump rotor with one-component rotor supports and

2 shows a second embodiment of a turbomolecular pump

Pump rotor with two-component rotor support bodies.

FIGS. 1 and 2 each show a multi-stage turbomolecule pump pump rotor 10; 40 shown. The pump rotor 10; 40 can rotate at rated speeds between 20,000 and 100,000 rpm. The two pump rotors 10; 40 are essentially the same structure and differ only in their internal structure.

The pump rotor 10 of Figure 1 is essentially formed by eight wing disc rings 17 which are axially braced together by two by a clamping screw 28 and a WeMe 30 axially braced clamping body 20, 22. Furthermore, the wing disc rings 17 is followed by a rotor-side Holweck cylinder 32. The pump rotor 10 is not formed in one piece, as is usual in pump rotors according to the prior art, but is composed of a plurality of flywheel rings 17. Each wing disc ring 17 is formed by a closed rotor ring 12, protrude from the radially rotor blades 16 to the outside, which in turn form a wing disc 14.

The rotor rings 12 are axially held together by the two axial clamping body 20, 22, which are braced axially by the clamping screw 28 and the shaft 30 together. The two clamping bodies 20, 22 each also have outer cylindrical rotor support bodies 24, 26, on the support cylinders 25, 27, 29, 31 of which the respective rotor rings 12 are attached. The rotor support bodies 24, 26 are used for the radial positioning or fixing of the rotor rings 12. The outlet-integral piece clamping body 22 is formed in three stages, and has three support cylinders 27,29,31 on. The rotor rings 12 sit with a slight clamping fit without gaps on the rotor support bodies 24, 26 and their support cylinders 25, 27, 29, 31.

The clamping screw 28 braces the rotor shaft 30, the pressure-side rotor support body 26 and the inlet-side rotor support body 24 axially together.

Each rotor ring 12 has an axial shoulder 15 at one or both axial ends. In the area of paragraphs 15 of the adjacent rotor rings 12, a reinforcing tube 18 made of glass fiber reinforced plastic (CFRP) is placed axially under prestress. The Armierungsrohre 18 take on rotation of the pump rotor 10 substantially on the generated by the centrifugal force in the rotor ring 12 tangential forces. In this way, 17 can be used as a material for the integral wing disk rings relatively inexpensive aluminum alloys. The pressure-side rotor support body 26 has on the inside a hollow space 38, which has sufficient space for the arrangement of a rotor bearing of the rotor shaft 30, wherein the rotor bearing is preferably a magnetic bearing.

As shown in FIGS. 1 and 2, a Holweck cylinder 32 can connect to the pressure-side end of the pressure-side rotor support body 26.

The pump rotor 40 of Figure 2 has compared to the pump rotor 10 of Figure 1 only a modified structure of the rotor support body and clamping body. In the present case, a total of three rotor support bodies 24, 42, 48 are provided. The einiassseitige rotor support body 24 forms with the central rotor support body 42 two clamping bodies 20, 43, through which the three inlet side FSügeischeibenringe 17 are clamped together axially. The remaining wing disc rings 17 'are not axially braced, but axially fixed to each other by other design measures.

The central rotor support body 42 and the pressure-side rotor support body 48 are each formed in two pieces and each consist of a disk body 44, 52 and a cylindrical support cylinder 46, 50. The disk body 44, 52 is made of aluminum and the support cylinder 46, 50 of carbon fiber reinforced plastic.

The two-component structure of the two rotor support bodies 42, 48 allows a further mass reduction of the rotor 40, whereby the kinetic rotation energy is reduced, which in turn has the consequence that the energy released in a rotor burst is lower, and realized higher speeds because of the reduced centrifugal forces can be.

Claims

claims

1. Multi-stage turbomolecular pump pump rotor (10; 40) with

at least two separate wing disc rings (17, 17 ^r ) each having a rotor ring (12) and at least one wing disc (14), and

a cylindrical Arrnierungsrohr (18) between the wing discs (14) of adjacent Flugischibenringe (17, 17 '), which comprises the rotor rings (12) of the Flugischeibenringe (17, 17') on the outside clearance.

2. Multi-stage turbomolecular pump rotor (10; 40) according to claim 1, characterized in that the material of the Armierungsrohres (18) is different from that of the Flugischeibenringe (17).

3. Multi-stage turbomolecular pump rotor (10; 40) according to claim 2, characterized in that the material of the reinforcing tube (18) is carbon fiber reinforced plastic.

4. Multi-stage turbomolecular pump rotor (10; 40) according to any one of claims 1-3, characterized in that at least one wing disc ring (17) has a single flywheel (14).

5. Multi-stage turbomolecular pump rotor (10; 40) according to one of claims 1 to 4, characterized in that the flyer disc rings are clamped axially between two rotor shaft clamping bodies (20, 22).

6. Multi-stage turbomolecular pump rotor (10; 40) according to any one of claims 1-5, characterized in that the rotor rings (12) of the Rotisserie disc rings (17, 17 ') are mounted on at least one rotor support body (24, 26, 42, 48).

7. Multi-stage turbomolecular pump rotor (40) according to claim 6, characterized in that the rotor support body (42, 48) consists at least partially of carbon fiber reinforced plastic.

8. A multi-stage turbomolecular pump rotor (10; 40) according to any one of claims 1-7, characterized in that the pump rotor (10; 40) has a cavity (38) for receiving a rotor bearing.

9. turbomolecular pump with a multi-stage turbomolecular pump rotor (10; 40) according to claim 8 and a rotor bearing, characterized in that the rotor bearing is a magnetic bearing.