EP2375074A2 - Rotor for a vacuum pump - Google Patents

Abstract

The rotor has a piston (38) comprising cover plates (42, 44) that are connected with a front end of a cladding body (40). The cover plates include respective transition plates (422, 442) that are connected with respective closing plates (420, 440) by a screw (60). The screw is held in an element that provides relative movements between the closing and transition plates. The transition plates are made of metal. The cover plates and the cladding body are made of fiber-reinforced composite material. The closing plates und the cladding body are vacuum-tightly connected with one another. An independent claim is also included for a vacuum pump comprising a cladding body.

Description

The invention relates to a rotor for a vacuum pump according to the preamble of the first claim.

Among the vacuum pumps, Roots pumps and screw pumps have been successful on the market for decades and have become indispensable in vacuum generation. By way of example, the use in metallurgy, vacuum drying and chemical engineering may be mentioned here. In both types of pumps usually two shafts are used, on each of which a piston is arranged. By rotation of the shafts and cooperation of the pistons, for example by intermeshing, gas is displaced and thus achieved the pumping action.

Conventionally, the pistons for this type of pumps are cast from a metal alloy, as for example in the introduction of DE 40 30 702 A1 is described. They are characterized by a high mass relative to the piston volume. The resulting high moments of inertia require high drive power of the pump and lead to high bearing loads. The solution described in the aforementioned patent document, the rotor to reduce weight from slices, has not prevailed. This may be due to disadvantages such as the risk of virtual leaks in the space between the panes and the effort required to ensure mechanical stability.

It is therefore an object of the invention to provide a rotor for a vacuum pump with an improved volume-to-mass ratio.

This object is achieved by a rotor having the features of claim 1. The further claims 2 to 10 indicate advantageous developments of this invention.

The features defined in the claims lead to a piston with a very good mass to volume ratio, whereby advantageous moments of inertia are achieved. The construction with a jacket body allows comparatively thin-walled pistons. The cost of materials is low, also come cheap manufacturing processes are used, so that a favorable manufacturability is achieved. The necessary drive power is reduced, as well as the load on the bearings. In addition, the proposed measures enable higher speeds, resulting in more compact vacuum pumps, which have a higher pumping speed per pump volume. The construction with lower masses and less massive components also has an advantageous effect in the case of rotor-rotor or rotor-housing contact.

With reference to embodiments and their developments, the invention will be explained in more detail and the representation of its benefits to be deepened.

Fig. 1:

Schnitt in Wellenrichtung durch eine Wälzkolbenvakuumpumpe,

Fig. 2:

Schnitt senkrecht zur Wellenrichtung durch eine Wälzkolbenvakuumpumpe entlang I-I',

Fig. 3:

Schnitt in Wellenrichtung durch einen Rotor für eine Wälzkolbenvakuumpumpe,

Fig. 4:

Teilschnitt durch die Deckplatte und den Mantelkörper,

Fig. 5:

Schnitt in Wellenrichtung durch einen Rotor für eine mehrstufige Wälzkolbenvakuumpumpe.

Show it:

Fig. 1:

Section in the shaft direction by a Roots vacuum pump,

Fig. 2:

Section perpendicular to the shaft direction through a Roots vacuum pump along I-I ',

3:

Section in the shaft direction through a rotor for a Roots vacuum pump,

4:

Partial section through the cover plate and the jacket body,

Fig. 5:

Section in the shaft direction through a rotor for a multi-stage Roots vacuum pump.

In Fig. 1 is a section through a Roots vacuum pump, hereinafter Roots pump shown. In the housing 2 of the Roots pump is the pump chamber 4. The Roots pump has a first rotor 10 and a second rotor 12. These are rotatably mounted in bearings 20, 22 and 24, 26. In a gear chamber 6 associated with the rotors synchronization gears 30 and 32 are arranged, which generate a synchronous rotation in the opposite direction of rotation and cause a contactless rolling of the rotors on each other. One of the rotors is driven via a magnetic coupling 34 by a motor 36 which is located in a drive section 8 of the housing.

Alternatively, can be dispensed with the magnetic coupling and a direct drive of the rotor can be provided. In addition, instead of the mechanical synchronization with the synchronization gears, an electrical synchronization can be provided in which then each of the two rotors is driven by a motor associated with it.

A section through the Roots pump along the line II 'is in Fig. 2 shown. Gas passes from the recipient, not shown here, into the Roots pump through a gas inlet flange 14. There it is conveyed by the opposite direction according to arrow arrow rotating piston, in the meantime enclosed in the pump chamber 4 and ejected through the gas outlet flange 16. The two rotors 10 and 12 have as Wälzkolbenprofil an approximately eight-shaped cross section, wherein each half of the. Eight corresponds to one wing. In its interior, the rotors are hollow, with the cross section of the cavity substantially following the octagonal cross section. In further developments, the rotors can also have more than two wings, for example three or four.

The in Fig. 3 section through one of the rotors along the axis shows its structure. It has a piston 38, with which the pumping action is achieved. At the opposite end faces shaft journals 50 and 52 are provided, which are supported by the bearings of the Roots pump. Also drive, magnetic coupling, Sychronisationszahnräder and oil distribution discs are arranged on this shaft journal. The piston is constructed of several parts which together define the cavity 54. These parts include the shell body 40, which is a cylinder with eight-shaped cross-section as in Fig. 2 and longitudinal axis along the axis of rotation 100 is designed. This jacket body is preferably made of carbon fiber reinforced plastic (CFRP), glass fiber reinforced plastic (GRP) or aluminum. The manufacture of the sheath body comprises, in the case of the first two materials, the winding of the fibers onto a shaped body. In the production of aluminum extrusion can advantageously be used, injection molding or die casting. With these materials, an advantageous ratio of wall thickness of the piston is achieved to volume. This results in low masses, high stability and cheap production.

The front side of the jacket body is closed by a first cover plate 42 and a second cover plate 44 on the opposite end side. Preferably, the transition from sheath body to cover plate is made vacuum-tight, so that a gas flow between the cavity 54 and the surroundings of the piston, i. et al the pump chamber, so far prevented that the vacuum data of the vacuum pump are not affected by gas escaping from the piston.

In the present embodiment, both cover plates are designed as composite components. Facing the cavity are respective closure plates 420 and 440. They are of the same material as the sheath body. Alternatively, different materials can be used in which case the thermal expansion properties must be taken into account. For example, a material with suitable thermal expansion can be used, ie the different expansion is such that it does not lead to tension that deforms the piston too much or even destroy. Too much deformation of the piston is given when the gaps between the pistons are consumed with each other or to the housing.

Transition plates 422 and 442 are connected to the closure plates. Their function is to create a transition between the shaft journal on the one hand and the closure plates on the other. Especially the use of CFRP or GFRP for sheath bodies and closure plates would require a direct transition to the metallic shaft journal. This is structurally difficult and is facilitated by the transition plates in an advantageous manner. The transition plate can be connected by welding, soldering, pressing or shrinking with the shaft journal. For this purpose, it is advantageous to make the transition plate of a metal alloy. The advantage of using shaft journals can be seen in the weight reduction and in the prevention of uneven thermal expansion of the sheath body and shaft.

Two advantageous types of connection between transition plate and closure plate are in Fig. 3 shown. One or more screws 60 make a direct connection. Alternatively or additionally, a tie rod 56 may be provided which completely penetrates the cavity and with which the transition plates are pulled against each other and thus against the closure plates.

In a development, a support wall 70 is provided within the cavity, which may have one or more holes through which the tie rods passed through. This support wall reduces the deformation latitude for the sheath body and thereby enables low wall thicknesses of the sheath body.

The area of the piston with closure plate, shell body, transition plate and screw is in Fig. 4 shown in more detail again. Sheath body 40 and closure plate 420 are connected to each other at connection 68. Advantageously, the jacket body surrounds the closure plate in the radial direction. The connection is made by gluing or by welding. The transition plate 422 terminates flush with the sheath body in the radial direction. In this way dead spaces are prevented. Since differences in the temperature expansion behavior between transition plate and closure plate can not be excluded, it is advantageous to arrange the screw 60 floating. For this purpose, the screw is taken in a relative movements between the closure plate and transition plate zulendem element. In a simple, cost-effective and also vacuum-tight manner, this succeeds in that an elastomeric sealing ring 66 is located between the screw head and the transition plate. The screw passes through a hole in the transition plate and is recessed. In the closure plate, the thread of the screw engages the thread of a glued threaded bushing 62. The gap 64 around the screw shaft allows uneven expansion of the transition plate and the closure plate, with the screw head floating on the seal 66.

Some further advantageous developments of the example described above are conceivable.

Instead of two shaft journals, a continuous shaft can be used. If such a continuous wave is used, care must be taken in a choice of materials of shaft and sheath body with different coefficients of thermal expansion, that stresses due to the uneven expansion be avoided. This is achieved, for example, by a floating design of the connection 68.

If the connection between 420 and 422 is to take place before the connection of the cover plate and the sheath body, it is advantageous to connect the end face 69 of the sheath body with the transition plate 422, for example by gluing or welding.

According to a development, the sheath body and at least one closure plate can be made in one piece. As a result, tightness and stability are further improved.

The rotor can be designed by suitable shape of the jacket body as a screw pump rotor. For this purpose, the cross section of the jacket body is adapted and provided for use along the rotor axis.

A development of the rotor is in Fig. 5 shown in section along the axis of rotation. The rotor 500 shown there is used in a two-stage vacuum pump. The structure described below can easily be extended to more than two pump stages.

The rotor has first and second pistons 502 and 504. The length L _{1 of} the first piston is greater than the length L _{2 of} the second piston. The first piston is thus adapted for use in the high-vacuum side pumping stage of a two-stage vacuum pump.

The first piston has cover plates 520 and 526, each formed as a composite of a closure plate 522 and 528 with a transition plate 524 and 530 are. Between the cover plates, a jacket body 532 is arranged. The transition plate 530 is connected to a shaft journal 570, which is intended to be received in a bearing of the rotor.

Analogous to the first piston, the second piston has cover plates 540 and 546, which in turn are formed by a combination of a closure plate 542 and 548 with a transition plate 544 and 550. Between the cover plates, a jacket body 552 is provided. The transition plate 544 is connected to a shaft journal 560, which in turn is intended to be received in a bearing of the rotor.

Both pistons are connected by a shaft piece. This shaft has sections 562 and 566. The portion 562 is connected to the transition plate 550 of the second piston, the portion 566 to the transition plate 524 of the first piston. The connection of the sections with each other must be designed so that it withstands the torques generated by rotation of the rotor during operation of the vacuum pump. Conceivable is a bond or a positive connections such as a dovetail. The least misalignment indicates the in Fig. 5 shown solution. The portion 562 has a projection 564 which engages a mating recess of the portion 566 and is secured by a pin 568. The multi-stage rotor according to the embodiment is very well suited for the modular construction of a series of multi-stage pumps, because for different members common parts, such as shaft journals, cover plates, closure plates, shell body, etc. are used.

Claims (10)

A rotor (10, 12, 500) for a vacuum pump having a piston (38, 502, 504), characterized in that the piston has a jacket body (40, 532, 552) and a cover plate (42, 44) connected to an end face of the jacket body 520, 526, 540, 546). A rotor (10, 12; 500) for a vacuum pump according to claim 1, characterized in that the cover plate (42, 44; 520, 526, 540, 546) has a closure plate (420, 440; 522, 528, 542, 548) and a transition plate (422, 442; 524, 530, 544, 550) connected to the closure plate. Rotor (10, 12; 500) for a vacuum pump according to claim 2, characterized in that a screw (60) grasped in a relative movement between closure plate and transition plate-permitting element (66) holds the closure plate (420, 440; 522, 528, 542, 548) and the transition plate (422, 442; 524, 530, 544, 550) interconnects. Rotor (10, 12, 500) for a vacuum pump according to one of claims 2 or 3, characterized in that closure plate (420, 440; 522, 528, 542, 548) and sheath bodies (40; 532, 552) are connected to one another in a vacuum-tight manner , Rotor (10, 12; 500) for a vacuum pump according to claim 4, characterized in that the material of the closure plate (420, 440; 522, 528, 542, 548) has a coefficient of thermal expansion which is so close to that of the material of the casing body ( 40; 532, 552) that no Leakage of the connection due to thermal expansion occurs. Rotor (10, 12; 500) for a vacuum pump according to one of claims 2 to 5, characterized in that the main component of the transition plate (422, 442; 524, 530, 544, 550) metal and the main component of closure plate (420, 440 ; 522, 528, 542, 548) and sheath body (40) is a fiber reinforced composite material. Rotor (10, 12; 500) for a vacuum pump according to one of the preceding claims, characterized in that a shaft journal (50, 52; 560, 570) is connected to the transition plate (422, 442; 530, 544). Rotor (10, 12; 500) for a vacuum pump according to one of the preceding claims, characterized in that it comprises a second piston (504). Vacuum pump, characterized in that it comprises a rotor (10, 12, 500) according to one of the preceding claims. Vacuum pump according to Claim 8, characterized in that the jacket body (40; 532; 552) has a rolling-piston profile in cross-section.

Images