The invention relates to an arrangement for sealing a propeller shaft of a ship according to the preamble part of claim 1, and a method for sealing the propeller shaft of a ship according to the preamble part of claim 6.
The propeller of a ship or a corresponding large watercraft is supported by bearings against the body of the ship or the propulsion unit. The propeller shaft has an arrangement of shaft seals between the body and the shaft to prevent the surrounding water from entering the body, and an arrangement of bearing seals on both sides of the bearing to prevent the bearing lubricant from leaking into the water or inside the body. The shaft seals must retain their sealing properties for as long as possible, as their reliability is of primary importance for the operation of the propulsion system and the reliability of the bearings that support the shaft. The shaft seals are located below the water surface, which means that hydrostatic pressure is directed at them. The shaft seals consist of several lip seals with seal chambers between them. This arrangement aims at distributing the total pressure differential into parts with the additional method of adjusting the pressure in the chambers by feeding air into the chambers or by connecting the chamber to an oil tank to keep the seal chamber pressure at the desired level through the hydrostatic pressure of the oil based on the force of gravity. Particularly in electric rudder propeller systems, in which the available space is very limited, all additional devices related to the shaft sealing system result in substantial space issues when using existing shaft sealing systems.
The service life of a shaft seal is affected by many factors, all of which must be brought to the best possible level. The most important factors affecting the performance and service life of the seal are the pressure differential over the lip seal, the temperature of the contact surface between the seal and the shaft, the circumferential speed of the outer surface of the shaft and the chemical impact of the lubricant affecting the seal material. The joint effect of these factors must be at an adequate and acceptable level to enable the seal to achieve its maximum service life according to its design.
The use of environmentally friendly oils, that is, biodegradable oils, sets additional requirements as their properties are more sensitive to factors such as the operating temperature.
A solution is known from the patent publication U.S. Pat. No. 5,683,278 in which compressed air is used to adjust the pressure in the chambers between the seals.
The purpose of the invention is to create a new shaft sealing system, particularly suitable for limited spaces, which maintains the optimal conditions at the lip seal and maximizes the service life of the seals. The arrangement according to the invention is characterized by the features specified in the characteristics section of claim 1. The method according to the invention is characterized by the features specified in the characteristics section of claim 6. Other preferred embodiments of the invention are characterized by the features defined in the dependent claims.
An embodiment according to the invention lengthens the service life of the seal through the optimization of the operational conditions. The adjustment of the pressure in the internal chambers of the sealing system keeps the pressure differential over the lip seals as low as possible, making it optimal for the service life during the entire operational life of the system. The heat output created at the seal is transferred by the circulating oil into the frame of the rudder propeller device and further into the sea water, keeping the temperature at the seal adequately low.
The medium used to pressurize the internal chamber cools the seal interfaces to the temperature range that is optimal for the seal performance. The cooling effect particularly makes more effective the utilization of biodegradable oils, as their properties are particularly sensitive to high temperatures. Thus the solution offers better conditions for the use of environmentally friendly oils.
In applications in which the shaft sealing is located within the body of the ship or the propulsion unit, away from the immediate vicinity of the shaft and the body, the water surrounding the ship does not necessarily cool the seal adequately. An embodiment according to the invention brings the cooling to an adequate level reliably and at low costs.
The invention enables the creation of optimal conditions for the seal in varying operational environments. As the draft of the ship changes, the pressure in the seal chambers is regulated so that the pressure differential over each lip seal is as low as possible. As the temperature of the environment, particularly the temperature of the water surrounding the propeller device, varies, the temperature of the seal contact surfaces can thus be kept as low as possible. Furthermore, the pressure in the chambers can be regulated according to the pressure of the surrounding water when the pressure variation is due to the operation of the ship. This will mainly concern CRP drives (Contra-Rotating Propeller drives) in which the pressure affecting the shaft line varies according to the ship operation condition.
An embodiment according to the invention introduces advantages related to manufacturing and production engineering. The same system suits many, even all, types of watercraft. An embodiment according to the invention can utilize standard seals, which guarantees availability and quality. The number of components required by the solution is small, resulting in lower costs and easier accommodation into the limited space of a rudder propeller device. The system can be designed into a modular composition, achieving benefits for the assembly and maintenance phases and the acquisition of raw materials. The system also includes measurement and adjustment devices which facilitate more effective condition monitoring, creating better prerequisites for life cycle management.
In the following, the invention will be described in more detail with the help of certain embodiments by referring to the enclosed drawings, where
The propulsion unit casing 4 comprises an intermediate compartment 16 on the propeller 6 side between the propeller 6 and bearing 14. The walls of the intermediate compartment 16 comprise the wall 18 on the propeller side, the outer circumference 20 of the propulsion unit end and the support structure 22 of the bearing 14. The propeller shaft 10 passes through the intermediate compartment 16 at the center of it. At the bearing end of the intermediate compartment 16 there is the outer oil seal 24 of the bearing, preventing bearing lubricating oil from leaking out of the bearing housing. Correspondingly, at the motor end of the bearing 14 there is the inner oil seal 25 of the bearing. Shaft sealing 26 is fitted at the propeller end of the intermediate compartment 16, preventing surrounding water from entering the intermediate compartment 16. The intermediate compartment 16 is thus completely sealed, and in normal operating conditions, it is also free of any liquid. The shaft sealing 26 is fitted inside the closed intermediate compartment, enabling replacement of the sealing within the compartment.
Between the first and the second chamber there is a third chamber 40, limited between the lip seals 32 and 34 and their contact surfaces facing the shaft. The third chamber 40 is connected to the oil tank 50 using a pipe 52, pump 54 and pipe 56. The pressure of the third chamber 40 is constantly regulated by the motor 58 operating the pump 54. The motor is controlled by a frequency converter 60. Pressure regulation devices are used to keep the pressure of the third chamber 40 at a value that corresponds to the pressure differential between the first and the second chamber so that the pressure differentials over the contact surfaces of the lip seals 32 and 34 are roughly the same. If the pressure in chamber 42, for example, is 0.1 bar and the pressure in the first chamber 38 depending on the draft is 0.7 bar, the pressure of the third chamber 40 is regulated at approximately 0.4 bar using the pump 54.
The pressure of the third chamber 40 is measured by a sensor 62. The measurement data is taken to the control unit 78. The PI controller 66 of the control unit calculates the rotation speed instruction to be sent to the frequency converter 60 based on the pressure measurement data 62 and 44. The second and third chambers are connected to a tank by discharge pipes 68 and 70 through a valve 72. A choker 74 is installed to the discharge pipe 70 for flow regulation. The choker is designed according to the maximum temperature of the seal chamber. The pressure regulation devices of this embodiment thus consist of a pump 54 and flow regulation choker 74. The operation of the pressure regulation devices is based on the pressure loss created by the choker 74 or another flow valve, due to the flow rate produced by the adjustable pump 54. The pressure loss created by the choker depends on the oil flow rate. The desired pressure in chamber 40 can thus be achieved by regulating the rotation speed of the pump by a frequency converter. Below the pump 54 the oil flow passes through a heat exchanger 76, which enables an efficient cooling function being achieved as a pressure regulation by-product through a simple arrangement. When the oil is warm and has low viscosity, the desired pressure in chamber 40 can only be achieved through a high flow rate. Due to the high flow rate, the cooling power is also at its best. When the oil is cold, the desired pressure can be achieved with a significantly lower flow rate. This means the oil that is already cool is not cooled unnecessarily. The heat exchanger may comprise, for example, a box that lies against the propulsion device frame, transferring the heat directly into the surrounding sea water. Alternatively, the oil tank can be located in the propulsion unit in an advantageous manner so that the tank is in contact with the surrounding water.
The described regulation system effectively keeps the pressures and temperature of the shaft sealing chambers within their rated values, ensuring the longest possible service life. At the same time, the use of biodegradable oils becomes possible without compromising the functionality of the sealing.
The intermediate compartment solution enables the replacement of all seals without the need for taking the watercraft to a dry dock, which makes maintenance and repair work easier.
The pressure differentials over the lip seals are kept at the lowest possible level in a controlled manner as the draft of the watercraft and the weather conditions vary. As the actual pressure of the surrounding water is also constantly measured, the pressure changes due to the movements and operation of the watercraft are also taken into account, which is an important factor for the CRP drive.
The pressurization arrangement according to the invention is not dependent on the structure of the sealing, but can be applied to most shaft sealing arrangements. The arrangement suits different ship types and all draft levels with no need to adjust the height of the oil tank as the draft changes.
In summary, the arrangement requires fewer pipes, tanks, level detectors and control valves, which, together with the simple mechanical structure, lower the costs compared to a conventional system.
The arrangement includes embedded pressure and pressure level measurements and monitoring, which can be utilized for condition monitoring purposes.
In an alternative embodiment, a similar system can also be arranged so that a pump produces a fixed flow rate and the pressure of the seal chamber 40 is regulated so that the PI controller 66 steers an electric flow rate valve (not illustrated in the attached figures) instead of a frequency converter.
In the above the invention has been described with the help of a certain embodiment. However, the description should not be considered as limiting the scope of patent protection; the embodiments of the invention may vary within the scope of the following claims.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/FI10/50993 | 12/2/2010 | WO | 00 | 7/24/2013 |