DE932704C - Turbine-driven fan with free-flying runner - Google Patents

Description

Turbine-driven fan with free-floating rotor Die The invention relates to a turbine-driven fan with a free-floating one Runner, the fixed bearing of which is at least partially in the hub part of the fan rotor protrudes.

In known designs of this type, the bearing shaft is with the rotors or rotors connected by means of a cylindrical part that extends over the bearing housing protrudes and has a collar arranged at a distance from the end of this part. When assembling the rotors with the bearing shaft, their hub parts are screwed together, until they non-rotatably -anli-egen on the collar of the bearing shaft, whereby the turbine rotor hub the circumference of the protruding bearing shaft part and the collar ring at least partially includes. On the protruding part of the bearing shaft that connects it to the Manufactures rotors, however, because of the required play during assembly the parts are not centered properly and the rotors are not held firmly in place. Furthermore, due to the relatively large contact area of the turbine rotor hub with the circumference of the the protruding part of the bearing shaft, the heat transfer from the hot turbine rotor strongly favored on the bearing shaft.

The purpose of the present invention is now to act as a carrier to form the rotors serving part of the bearing shaft in such a way that these disadvantages known designs of free-floating rotors or rotors are omitted.-This is achieved according to the invention that a frustoconical as a support piece for the rotors trained, central part of the bearing shaft is provided and the fan rotor for making a detachable connection with the turbine rotor has a hub-like approach designed to match, with which it is used during assembly Both rotors mounted on the frustoconical support piece of the bearing shaft in a rotationally secure manner will.

With this design, the bearing shaft is pulled onto the fan rotor by means of the centric. arranged, cone: bump-shaped connecting piece entirely achieved the desired centering of the rotors with the bearing points and a maximum firm connection established. Furthermore, in the new version a contact of the turbine rotor with the lateral surface of the support piece of the bearing shaft avoided so. that the heat transfer from the turbine rotor to the bearing shaft as possible is small.

The hub of the fan rotor can be used to introduce the turbine rotor disk have an axially open, annular recess. The training becomes advantageous chosen so that the connection of the two rotors by means of an external thread on the hub of the turbine rotor and internal thread of the outer wall of the axiaal open, annular Recess of the fan rotor hub can be designed in such a way that the thermal expansion the hub of the turbine rotor, which is hot during operation, the pressure of the screw connection both rotors increased.

To reduce the heat transfer from the turbine rotor to the bearing, can e.g. B. from an oil supply channel in the fixed storage over at least a nozzle injected fresh oil onto the frustoconical support piece of the bearing shaft will. To enlarge the oil-splashed surface of the frustoconical support piece this surface can be increased even further by means of recesses arranged in the support piece be. A centering pin can be placed in the middle of the turbine rotor disk and a truncated cone-shaped one Part of the bearing shaft a matching centering hole can be provided for the centering of the two rotors to facilitate. Of those who are directly related to each other Hub surfaces of the two rotors can each have at least one partial surface as a guide and centering surface.

The drawing shows two exemplary embodiments of the subject matter of the invention shown, namely Fig. i shows an axial section through the two rotors of the first embodiment and Figure 2 shows a same section of the second embodiment.

The same numbers denote the same or similar parts in all figures.

In Fig. I, the two rotors with i and 2, the fan side protruding into the Gebläsero @ tor housing part with 3 and the connection of the two rotors with q. designated. The rotors are supported on a centrally arranged part 5 'of the bearing shaft 5a, which is frustoconical. The connection of the rotors is designed so that when the parts are assembled, the turbine rotor pulls the fan rotor onto the frustoconical part of the bearing shaft and the turbine rotor is then supported on the end face 5'b of this shaft part. I; The outer surface 5'c of the truncated cone lies centrically to the bearing surfaces 5'd and serves as a centering surface for the radial bearing of both rotors, but is not in direct contact with the turbine rotor i. This is particularly advantageous because it reduces the heat transfer from the hot turbine rotor to the bearing surface 5'd. The connection q of the parts is achieved in that the internally threaded hub part ia of the turbine rotor is screwed to an externally threaded hub: 2a of the fan rotor. With this screw connection, the fan rotor is drawn onto the frustoconical extension 5 '. There are also special means for reducing the heat transfer from the hot turbine rotor to the bearing are provided. Such a means consists in that from an oil supply channel in the fixed bearing 3 via at least one nozzle 6 cold oil to the '. frustoconical part 'of the bearing shaft is injected. For the same purpose, this shaft part has open recesses on the face 5'b facing the turbine rotor, which reduce the contact area. So that the cooling effect of the oil sprayed by the nozzle 6 onto the frustoconical shaft part is greater, in the present exemplary embodiment the surface of the frustoconical shaft part opposite the nozzle is provided with a recess 5'e. In the middle of the turbine rotor disk there is a pin ic which protrudes into a bore 5'f in an exactly fitting manner. This embodiment aims at an even more precise centering of the two rotors with the bearing surfaces 5'd, the inaccuracy resulting from the radial play of the screw connection being eliminated.

Fig. 2 shows a further embodiment of the subject matter of the invention. In this embodiment, the hub 2 ä of the fan rotor 2 has an axially open, annular recess 2b, which receives the hub of the turbine rotor shaft ia ', the connection q.' Both rotors are produced by an external thread on the hub of the turbine rotor and an internal thread on the outer wall of the open recess of the fan rotor hub. With this training of the parts. ' the thermal expansion of the hub of the turbine rotor, which is hot during operation, increases the radial pressure on the part of the fan rotor hub that carries the internal thread. At the same time, the centering of the two rotors is improved and good cooling of the hub of the turbine rotor is achieved by the fan rotor. The extension 5 'of the shaft 5 is also mounted in a bore 5c' of the relatively cold fan wheel hub and only touches the turbine rotor at 5'b.

The main advantage of the present invention is that the frustoconical shaft part and its extension serving for storage one perfect centering of the fan and turbine rotor with the intended Screw connection also made for the highest speeds. Furthermore, the heat transfer of the hot turbine rotor on the bearings with the specified means effective scaled down. The training of the bearing points can, as shown, or in another of any kind can be provided.

Claims (7)

PATENT CLAIMS: i. Turbine-driven fan with free-floating rotor, the fixed bearing of which protrudes at least partially into the hub part of the fan rotor, characterized in that a frustoconical central part (5 ') of the bearing shaft and the fan rotor are provided as the support piece for the rotors (i, 2) (2) to produce a detachable connection (4, 4 ') with the turbine rotor has a suitably designed, hub-like extension (2a, 2d) with which it is pulled onto the frustoconical support piece (5') when the two rotors are assembled. 2. Blower according to claim i, characterized in that that the outer surface (5'c or 5 c ') of the frustoconical shaft part (5') only is in contact with the fan rotor. 3. Blower according to claim i, characterized in that that the hub of the fan rotor has an axially open, annular recess (2 b) for Receipt of the hub (i ä) of the turbine rotor (Fig.2). 4 .. blower according to claim 3, characterized in that the connection of the two rotors by means of an external thread on the hub of the turbine rotor and internal thread of the outer wall of the axial open, annular recess of the fan rotor hub is designed such that the thermal expansion of the hub of the turbine rotor, which is hot during operation, the pressing pressure the screw connection of both rotors increased. 5. Blower according to claim i, characterized characterized in that from an oil supply channel in the fixed bearing over at least one nozzle (6) fresh oil to the frustoconical support piece (5 ') of the Bearing shaft is injected. 6. Blower according to claim i, characterized in that the frustoconical support piece (5 ') of the bearing shaft on its on the turbine rotor the end face (5'b) coming into contact is a recess which reduces the contact surface having. 7. Blower according to claim 5, characterized in that the oil-splashed Surface of the frustoconical support piece (5 ') to improve the cooling effect is enlarged by recesses (5e 'or 5'e) arranged in the support piece. B. Fan according to claim i, characterized in that the turbine rotor has a middle centering pin (i c) and the frustoconical part (5 ') of the bearing shaft has a matching center bore (5'f). G. Blower according to claim i, characterized characterized in that of the hub surfaces that are in direct communication with one another of the two rotors at least one, partial surface as a guide and centering surface is trained. Cited publications: German Patent No. 686 814; U.S. Patent No. 2,322,824.