DE19647948A1 - Gondola propelling system for ship or windmill - Google Patents

Abstract

The gondola (1) suspended in a vertical tunnel (4) through the hull (3) contains a polyphase induction motor whose rotor (8) and stator (15) drive the respective propellers (7,12) in opposite directions. The axis of the stator is a hollow shaft (11) centred in a supporting bearing (16) with a sealing disc (13) at the other end. The rotor axis (6) rotates in a thrust bearing (9) with a supporting bearing (10) at the other end within the hollow shaft. Diameter and pitch of the propellers are chosen so that at nominal flow rate in the forward direction they co-operate at equal torque with optimal efficiency of propulsion.

Description

The state of the art for ship propulsion with a Gondola propeller (product name "Azipod") is detailed described in the lecture of March 3, 95 by Mikko Niini "The Need For Enhanced Maneuverability" held at the Seatrade Cruise Shipping Conference in Miami. He describes the Azipod as the propulsion system for ships of the future that can only be improved through counter-propellers at each end of the gondola, whereby the hydrodynamic efficiency by up to 15% could be improved. The practical implementation is still missing (see page 7).

A solution to the problem is in the attached view drawing and claims 1 to 14. spelled out. However, the Azipod doesn't just have advantages. The disadvantage is z. B. the high weight and the large Nacelle diameter, the not easy suspension of the heavy gondola, the low center of gravity and the associated high torques by rudder and thrust forces in the aft ship must be included.

These problems are also said to be due to the inventive Solution can be reduced. The one mentioned below "Contrapod" is exemplary in the simplified Sectional drawing shown.

As is known at Azipod, a gondola 1 with a streamlined hollow web 2 is guided through a vertical shaft 4 through the ship's hull 3 and rotatably suspended on a thrust and torque-absorbing tread 5 . For the propeller drive, the nacelle also receives an induction machine, which can be an asynchronous, a direct current or a 3 or multi-phase synchronous machine (permanently or externally excited).

According to the invention, two axes are arranged instead of a propeller axis. A shaft 6 receives a propeller 7 and is driven by the rotor 8 (rotor propeller 7 , rotor axis 6 ). The axis receives a thrust and support bearing 9 for the nacelle housing 1 and a second support bearing 10 which is arranged in the hollow shaft 11 . This hollow shaft forms the axis of the counter propeller 12 . The hollow shaft 11 is sealed against the ingress of water by a wall or a tight disk 13 and is non-positively connected to the stator housing 14 and the stator 15 . The hollow shaft is called the stator axis 11 . On the rotor propeller side, the stator axis and thus the stator housing 14 are centered and fixed on the rotor axis 6 by a support bearing 16 . The interior of the gondola is sealed off from the surrounding water by glands 17 at the ends of the gondola.

The system also works if the stator 15 is interchanged with the rotor 8 . The smaller flywheel mass, ie the rotor, should preferably be arranged on the outside (outer pole type).

An induction motor is preferably chosen to be an externally excited synchromotor as a brushless machine, ie with inductive excitation current transmission 18 . A converter feed of the stator current must be provided for speed control of the propellers. It takes place via slip rings 19 and brushes 20 . Both speeds must be measured (for stator and rotor).

The voltage of the motor is via the excitation current converter always set so that they are proportional on average the sum of the absolute values of the actual speeds of rotor and stator.

The propellers should be tested in the towing channel be examined and interpreted in such a way that they provide optimal thrust in advance with the same torque generate, but also enable a good stopping. Speed control is based on the target speed for a propeller, if possible for the one with the  highest rated speed. In rough seas or rowing one speed increase at the expense of the other so there is always optimal thrust and the risk of cavitation reduced.

The propeller, stator and rotor should therefore be capable of overspeed in a necessary range (n _ü ). In the case of haveries or actions that can more or less stop one propeller, the other will go into overspeed. To ensure that n _{ü is} not exceeded, both speeds are recorded and a speed limit n _{gr is} provided (n _gr less than n _ü ). If n _{gr is} reached, the converter limits the current or torque.

In the event of a serious havery of a propeller (blade or propeller completely lost) or in the event of a defective thrust or support bearing 9 or 10 , a provided locking device (e.g. brake) could fix the stator or rotor axis. The drive could continue to operate at half the power at half the power.

What are the advantages of the Contrapod over the Azipod?

• = Weight and volume reduction more than 50% On the one hand, this results from the fact that the relative speed between stator and rotor in the Contrapod is twice as large as the Azipod with the same Propeller speed. With the same performance can the torque and thus approximately the weight of the Contrapod be halved. Even if an additional rotating motor housing housed must result in a further reduction in performance through the better electrical and hydrodynamic efficiency of the Contrapod.
• = Better length / width ratio in terms of flow the gondola. The diameter of large three-phase motors  is determined by the required minimum pole width (approx. 250 mm). Since here the number of poles halved a slimmer gondola is possible.
• = Shallow draft possible for the largest ships. With the same thrust load on both propellers Systems could be the diameter of the propeller and thus the necessary draft with the Contrapod by approx. 30% be less.
• = Low-noise ship propulsion. Since there is no foundation for the Contrapod's engine there have torque generation of the engine than Harmonics have no influence on the ship. Furthermore, propeller blade impacts the outer skin of the ship cut in half by 2 propellers. Finally, the cavitation with dynamic, e.g. B. Influences of the sea due to the speed adjustment of the two propellers avoided.
• = Efficiency improvement by a maximum of 17%. This results from:
  • - Hydrodynamic through the counter propellers by 14%
  • - Due to the slimmer gondola: 1%
  • - Due to the better engine efficiency: 2%
• = 50% redundancy drive for propeller or bearing failure. The propeller axis in question can be locked be made.

With contra-rotating propellers (CRP), the one after the other are arranged (DE 42 34 584 A1 and DE-A 12 48 503) the storage and sealing of the massive inner shaft in the hollow shaft is the critical point of the CRP system. So that there are no different deflections of the Shafts with the bearing and sealing problems that occur occur, the inner wave must be larger than from Torque forth can be selected required.

The solution according to the invention according to claims 1 and 2 makes the problem uncritical and, with subclaim 11, facilitates assembly and maintenance of this bearing 10 and sealing of the sealing cover 13 which can be unscrewed from the outside ( FIG. 2).

The undesirable slip rings 19 requiring maintenance can be dispensed with if, according to FIG. 3, an asynchronous machine with its rotor 24 is placed on one of the rotating shafts, here the inner shaft 6 , and the stator 23 is arranged in the nacelle housing 1 . The number of poles of the asynchronous machine should be small (2 to 4 poles) compared to the multi-pole synchronous machine. If the slip is less than 1 (driving by motor), a small part of the mechanical power is then applied to the shaft 6 . The predominant slip power is then conducted via the fixed line 22 from the rotor 24 of the As machine to the stator 15 of the synchronous machine.

To keep the machines small, the main part should the reactive power of the As machine applied by capacitors will.

According to the invention the As-machine rotor machine As is shown in FIG. 3 24 is not placed on the hollow shaft 11, but on the inner shaft 6 and the rear propeller 7 associated, on the one hand the performance of the rear propeller is increased and on the other hand the diameter of the kept smaller can be. This fixed arrangement of the machines enables the desired increase in the power of the rear propeller to increase the overall quality of the CRP system. The required higher speed of the rear compared to the front propeller is achieved by appropriate choice of their gradients.

Because the rear propeller improves its efficiency u. a. from the recovery of the swirl energy of the front Propellers get, but preferably not in the end vertebrae the wing of the front propeller should reach in, the diameter of the rear propeller will be about 80  designed to 95% of the front.

The reduction in the performance of the synchronous machine Cost of the As machine by its mechanical performance depending on the hatching approx. 5 to 20%. Because the performance share the synchronous machine determines the nacelle diameter, there is also a possibility in the division of benefits the efficiency optimization of the CRP system.

The Contrapod becomes a wear-free CRP system if inductive transmission is also used for the excitation power. If you place this transmission device 18 on the hollow shaft 11 in front of the synchronous motor housing 14 and through this leads the feed 21 to the magnet wheel, there is an overall arrangement of the machines which, according to the invention, allows a streamlined teardrop shape to the main inflow direction of the nacelle housing 1 .

As previously described, is in the case of propeller or bearing damage after locking the one rotating system Emergency operation possible with the remaining system.

Claims (14)

1. A Populsionsanlage with a gondola, which is suspended in a vertical tunnel fixed or rotatable and is connected to a fluidically clad web below the ship's bottom and which contains a three- or multi-phase induction motor, characterized in that at each end of the gondola counter-rotating Propellers are driven, the one propeller with the rotor on one axis (rotor axis) and the counter-propeller with the stator on a coaxial shaft (stator axis) are non-positively attached (inner pole motor type) that the rotor axis is fixed in the nacelle housing by a support and thrust bearing and that the second support bearing is located in the hollow shaft of the stator, that the stator hollow shaft is sealed off from the propeller, has a support and thrust bearing for the nacelle housing and is non-positively connected to the stator housing and this is centered on the rotor propeller side by the second support bearing on the rotor axis is fixed u nd that each axis is sealed with a stuffing box to the housing against water ingress. 2. After 1, characterized in that in the gondola The rotor and stator are interchanged (outer pole type of the Induction motor). 3. After 1. and 2., characterized in that the propeller designed in terms of their pitch and diameter are that they flow in the forward direction at nominal flow optimal propulsion efficiency at the same torque have in cooperation. 4. After 1. to 3., characterized in that the motor rotor and stator is equipped with an overspeed capability above nominal speed (n _ü ) and that stator and rotor speed are detected that speed control only at one of these speeds - preferably the higher - he follows. 5. After 1st to 4th, in that there is an instantaneous torque limitation (Current limitation) occurs when a specified speed limit of the rotor or Stator is exceeded operationally. 6. After 1. to 5., characterized in that on the stator housing a locking option (e.g. brake) is provided and when the stator is locked, the drive of the rotor propeller with approximately half the supply voltage he follows. 7. After 1. to 6., characterized in that the engine is an externally or permanently excited synchronous machine. 8. After 7., characterized in that at a separately excited Synchronous machine the excitation current inductive to the magnet wheel and the stator current via slip rings is transferred to the stator and supplied by the converter becomes. 9. After 1. to 8., characterized in that the required Voltage for the motor is approximately proportional to the sum of the absolute values of the actual speeds is provided by the rotor and stator. 10. After 1. to 7., characterized in that also for the rotor axis can be locked in case of a fall is available. 11. After 1. to 10., characterized in that the sealing the hollow shaft to the bearing of the solid shaft  Cover is mountable from the propeller side of the hollow shaft. 12. After 1st to 7th and 9th to 11th, characterized in that the opposing multi-pole synchronous machine its stator current from one on one of the two rotating shafts seated rotor of a low pole, preferably two or receives four-pole asynchronous machine, its stator is fixed in the pod housing that the absorption power the ace machine into a mechanical and a much larger one electrical part is divided as the rotor current the As machine via a line to the stator of the Synchronous machine is given. 13. After 12., characterized in that the in advance front propeller sits on the hollow shaft and from that Rotor of the synchronous machine is driven that therefore the rear propeller has the higher power and from the asynchronous machine and the stator of the synchronous machine is driven over the solid axis and that the transmission excitation power inductively or through slip rings to the hollow shaft and via cables to the pole windings the synchronous machine takes place. 14. After 13., characterized in that the front propeller is bigger and turns slower than the rear one and that the housing by the chosen arrangement of the machines streamlined - in the form of drops - designed for the main inflow becomes.