EP2665642A1

EP2665642A1 - Rudder propeller with an underwater mechanism comprising a planetary gearing

Info

Publication number: EP2665642A1
Application number: EP12700160.0A
Authority: EP
Inventors: Manfred Heer
Original assignee: Schottel GmbH
Current assignee: Schottel GmbH
Priority date: 2011-01-20
Filing date: 2012-01-05
Publication date: 2013-11-27
Also published as: JP5913370B2; US20130303038A1; JP2014504705A; WO2012098022A1; KR20140004706A; DE102011009070A1; CA2825004A1; US9415851B2; CN103328324A

Abstract

The invention relates to a rudder propeller with an underwater mechanism comprising a planetary gearing, the planetary gearing comprising a sun gear (6), a fixed internal gear (4) and planetary gears (5), mounted between the sun gear and the internal gear and running on planetary axles (3) of a planet carrier (5), wherein the planetary gears are mounted on the planetary axles by means of hydrodynamic slide bearings (50).

Description

Rudder propeller with a planetary gear comprehensive underwater gearbox

The invention relates to a rudder propeller with a planetary gear comprising underwater transmission, wherein the planetary gear comprises a sun gear, a fixed ring gear, and between the sun gear and ring gear and mounted on planetary axles of a planet carrier planet carrier.

Rudder propellers of the type mentioned are known for example from DE 28 43 459 A1. The rudder propeller is used for propulsion and control of a watercraft, wherein the engine torque of a drive motor usually disposed within the vessel is transmitted from an overhead drive via a vertically downward drive shaft to an underwater transmission, which usually comprises an angle drive and a downstream planetary gear from where the motor torque is ultimately transmitted to the horizontal propeller shaft carrying the propeller. The underwater transmission is arranged in a housing rotatable about the vertical axis for the purpose of controlling the watercraft.

Within the reduction of the speed of the drive motor at a slow speed, ie at a speed suitable for the propeller shaft, Tengetriebes designed the usual in the art rolling bearing of the planetary gears critical, since they are subjected in the operation of the rudder propeller considerable loads, especially alternating loads. The rolling elements of the rolling bearings used can therefore not run optimally and are susceptible to wear. It has therefore already been proposed to use multi-layer roller bearings instead of rolling bearings of the planet on the planetary axes, but this storage is very costly.

The object of the present invention is therefore to avoid the disadvantages of the known embodiments and to ensure an increased life and reliability of such a rudder propeller at low cost and easy installation.

To achieve the object, the design of a rudder propeller is proposed according to the invention with the features of claim 1.

Advantageous embodiments and further developments of the inventions are the subject of the dependent claims.

The invention proposes to support the planet wheels by means of hydrodynamic slide bearings on the planetary axes, so that the entire width of the planetary gears and the maximum diameter of the same becomes usable, which is reflected in higher rigidity, longer life and reduced wear.

Due to the properties of the usually functioning with a lubricating oil hydrodynamic plain bearings extremely quiet and wear-free continuous operation of such a planetary gear is made possible, which can be easily produced.

Since in hydrodynamic plain bearings the coefficient of friction is a function of the rotational speed, ie the relative speed between the sliding surfaces, this is a static friction at a standstill via mixed friction at a low Speed in the desired fluid friction of the lubricating film at a sufficiently high speed over. Since marine drives such as rudder propellers are usually operated at normal speed of the ship at a certain rated speed or only a small speed range, the inventively proposed hydrodynamic sliding bearing can be tuned to this speed range.

At the arrival and departure of the rudder propeller and also when operating at changing speed, z. Example, when maneuvering to overcome the typical for low speeds or speeds mating is proposed according to a proposal of the invention that the planetary axes feed channels for a lubricant, which extend from a feed opening to the hydrodynamic sliding bearing. Thus, it is possible in these

Speed or speed ranges in which static or mixed friction is present to deliver lubricant at a suitable pressure to the hydrodynamic journal bearings to facilitate the transition to the desired fluid friction.

According to one proposal of the invention, this pressurization can be realized via the feed channels of the already existing lubrication system of the rudder propeller or separate lubricant pumps are provided for this purpose. The control can be made speed-dependent by a corresponding control device of the rudder propeller. Once the speed range is reached in which liquid friction prevails due to the prevailing relative speed between the sliding surfaces, the supply of lubricant can be switched off via the supply channels, since then it is no longer necessary.

The feed ports are connected according to a proposal of the invention with a common, formed in the planet carrier supply channel for the lubricant such that they communicate with each other. In that regard, a central lubricant supply is created within the planet carrier, which is in all, outgoing from the planet carrier planetary axes for the individual planet wheels branch. A planetary gear comprises at least two, preferably three such planetary gears together with planetary axes.

The pressure of the lubricating agent which can be applied to support the start-up or run-off of the planetary gear lies in a low pressure range of a few bar, which can be easily realized by the already existing lubrication system of the rudder propeller.

The hydrodynamic slide bearings are advantageously formed on their outer surface facing the planetary gear with a circumferential groove into which the feed channels open, so that the lubricant film can form directly around the hydrodynamic slide bearing.

To create a compact as possible, easy to install unit, the planetary axes are used on one end face of the planet carrier protruding in corresponding receiving holes, preferably shrunk.

According to a further proposal of the invention, the planet wheels are mounted by means of the hydrodynamic sliding bearing flying on the planetary axes, so that it is possible to use the entire tooth width of the planet gears for power transmission.

The planetary gears are secured according to a further proposal of the invention on the side remote from the planet carrier by means of a thrust washer against axial displacement on the planetary axis.

Further details and embodiments of the invention will be explained in more detail with reference to an embodiment illustrative drawings. Show it:

Figure 1 is a fragmentary view of a planetary gear according to the invention; Figure 2 shows the underwater transmission of a Rudderpropellers after

State of the art.

FIG. 2 shows, in a simplified schematized illustration, the underwater gear of a rudder propeller according to the prior art.

From a non-illustrated and arranged above water drive motor runs in bearings 100, 9 mounted drive shaft 10 in the vertical direction, which ends within the illustrated underwater transmission in a pinion, which is in engagement with a bevel gear 8 and forms an angular drive together with this. The bevel gear 8 is mounted on a horizontally extending propeller shaft 1, which at one end (not shown) carries a propeller. Via a coupling 7, the bevel gear 8 is in engagement with a sun gear 6 of a planetary gear, wherein the other components of the planetary gear drive a planet carrier 2 with several on one end side projecting planetary axles 3, located thereon rolling bearings 5a for supporting planetary gears 5 and a fixed ring gear 4 are. The fixed ring gear 4 is not shown in detail, e.g. connected to the housing, not shown, of the underwater transmission. On the other hand, the planet carrier 2 is shrunk onto the propeller shaft 1, so that the rotational speed of the drive shaft 10 is reduced after being deflected by the bevel gear 8 from the planetary gear into the slow and in this reduction, the propeller shaft 1 is driven. The roller bearing used in the illustrated embodiment of Figure 2 on the bearings 5a of the planet gears 5 is very susceptible to wear because of the alternating loads occurring.

In the case of the solution according to the invention shown in FIG. 1, a hydrodynamic sliding bearing 50, which supports the planetary gear 5 on the planetary axis 3, is mounted on the planetary axis 3.

The planetary axis 3 is shrunk into a corresponding receiving bore 21 of the planetary carrier 2 and has an axial first of a one Feed opening 300 extending supply channel 30 for a lubricant, which branches off at a right angle outgoing and leads to a formed on the outer surface of the hydrodynamic sliding bearing 50 groove 50. The feed opening 300 of the feed channel 30 communicates with a feed channel 20 formed in the planet carrier 2, so that it is possible to guide a lubricant flow via the feed channel 20 into the individual feed channels 30 by a lubricant pump, not shown in detail, for example the usual lubricant pump provided within the underwater gear , which will be explained in more detail below.

On the side facing away from the planet carrier 2, the hydrodynamic sliding bearing 50 and the planetary gear 5 mounted thereon are secured by means of a thrust washer 51 against axial displacement on the planetary axis 3.

Furthermore, one recognizes a part of the housing 12 of the underwater transmission and an associated housing cover 120, which jointly store the ring gear 4 of the planetary gear fixed. In operation of such a designed underwater gear for a rudder propeller is at standstill of the same a static friction between the sliding bearing 50 and the planetary gear 5 mounted thereon. If now the rudder propeller be put into operation, ie, the drive shaft 10 and the downstream parts of the underwater gearbox are set in rotation, then first a corresponding control command of the control of the rudder propeller, a lubricant flow at a pressure of less bar, for example up to 3 bar the feed channel 20 and the adjoining these feed channels 30 in the circumferential groove 500 of the hydrodynamic sliding bearing 50 pressed to overcome the occurring at low speeds or speeds mixed friction within the hydrodynamic sliding bearing 50 as quickly as possible. As soon as the mixed friction, which decreases with increasing rotational speed, changes into the fluid friction characteristic of the hydrodynamic slide bearing, the lubricant flow or the pressurization with the lubricant via the feed channel 20 and the feed channel is interrupted. le 30 turned off, so that by the pumping action of the surfaces of hydrodynamic sliding bearing 50 and planetary gear 5 required for the storage lubricating oil film is achieved and so far the planetary wheel almost wear-free and using the full tooth width between the fixed ring gear 4 and the sun gear 6 rotates.

In addition to the above-explained lubricating oil support during start-up of the planetary gear, such a lubricating oil assistance in the course of expiration, i. When the speed drops from the region in which liquid friction prevails, be effected by the corresponding control.

Claims

1. Rudder propeller with a planetary gear comprehensive underwater transmission, wherein the planetary gear a sun gear (6), a fixed ring gear (4) and between the sun gear (6) and ring gear (4) and running on planetary axles (3) of a planet carrier (2) mounted planetary gears (5), characterized in that the planetary gears (5) by means of hydrodynamic sliding bearing (50) are mounted on the planetary axles (3).

2. Rudder propeller according to claim 1, characterized in that the

Planetary axes (3) supply channels (30) for a lubricant, which extend from a feed opening (300) to the hydrodynamic sliding bearing (50).

3. Rudder propeller according to claim 2, characterized in that the feed openings (300) communicate with a common, in the planet carrier (2) formed feed channel (20) for the lubricant.

4. Rudder propeller according to one of claims 1 to 3, characterized in that the hydrodynamic sliding bearing (50) can be acted upon by the start of the rudder propeller with lubricant.

5. Rudder propeller according to claim 4, characterized in that the pressure of the lubricant is up to 3 bar.

6. Rudder propeller according to one of claims 2 to 5, characterized in that the hydrodynamic sliding bearing (50) on its the planet (5) facing the outer surface with a circumferential groove (500) are formed, in which open the feed channels (30).

7. Rudder propeller according to one of claims 1 to 6, characterized in that the planetary axles (3) on an end face of the planet carrier (2) are inserted into corresponding receiving bores (21) above.

8. Rudder propeller according to one of claims 1 to 7, characterized in that the planet gears (5) by means of the hydrodynamic sliding bearing (50) are mounted on the planetary axes (3) flying.

9. Rudder propeller according to one of claims 1 to 8, characterized in that the planet wheels (5) on the planet carrier (2) facing away by means of a thrust washer (51) are secured against axial displacement on the planetary axis (3).