The present invention relates to a power plant system comprising a propeller, a mechanical drive train, an electric motor, and an electronic controller for the motor. In particular, the invention relates to a means of protecting the propeller and the mechanical drive train from the full effect of mechanical shocks resulting from sudden cessation of propeller motion, such as is caused by fouling of the propeller by an underwater obstacle.
Older types of mechanically driven (turbine or internal combustion engine) icebreaker vessels have used a drive train comprising a propeller on a shaft driven directly from the mechanical power plant. In such icebreakers, the integrity of the propeller and drive train can be put at risk if the propeller hits a large block of ice, since it may be forced to stop very rapidly (say, in 0.5 seconds) against the torque delivered by the power plant, thereby putting an unacceptably large mechanical shock loading on the propeller and the drive train.
In other more recent types of icebreaker, in which an electric motor is directly coupled to the propeller through a shaft, there has been less need to interpose fluid couplings in the drive train because the electric motor has the ability to stop rotating very rapidly, unlike a turbine or diesel engine. Nevertheless, the propeller shaft still has to be rated for the forces caused by the stopping of the electric motor's rotary inertia. This is true no matter whether the motor and drive train is mounted in the hull of the vessel, or in a propulsion pod outside the main hull.
However, it has recently been proposed to use so-called “thrusters” for icebreakers, see
It is desirable to reduce the size of the motor by using step-down gearing, thereby allowing the motor to run at a higher RPM than the propeller. Unfortunately, this may expose the propeller to excessive torsional shock load, by virtue of the disproportionate effect of the gearing, because when referring a particular component of shaft system inertia to the propeller via step down gears of speed ratio N, the inertia experienced by the propeller is effectively multiplied by N2. Thus, the drive train with its gearing magnifies the motor's rotary inertia, as seen by the propeller, and increases the forces on the shaft and gears in an ice-stalling or other propeller-fouling event. To avoid damage to the propeller and drive train, a fluid coupling can again be inserted between the electric motor and the gears.
Unfortunately, such fluid couplings incur significant power transfer efficiency losses, which wastes fuel and energy.
The present invention provides anti-shock control in thrusters or other electric motor propulsion systems used in icebreakers and other water-borne vessels, so that they are better adapted to withstand stalling shocks to the drive train, caused by fouling of the propeller.
According to the present invention, a power plant system comprises a propeller, a mechanical drive train, an electric motor, means for controlling output torque of the motor to the drive train, and an emergency motor torque control means, the emergency motor torque control means comprising:
In this way, deceleration of the motor is increased beyond that of the drive train, so reducing the shock to the propeller and drive train if rotation of the propeller is excessively impeded. It will be appreciated that in the severe case of the propeller striking a solid underwater obstruction, such as a large block of ice, the invention protects the integrity of the propeller and drive train by reducing the amount of rotational stored energy transferred into the obstruction.
The means for controlling motor output torque preferably comprises an electronic vector controller and means inputting a torque reference signal to the controller, the torque reference signal being representative of a desired motor output torque. Hence, the means operative to reduce or reverse the torque applied to the mechanical drive train by the motor may conveniently comprise means for changing the torque reference signal to a low or a negative value.
The means for detecting excessive deceleration of the motor may comprise means for sensing deceleration of the motor, means for comparing sensed deceleration values with a threshold value representing an excessive deceleration and means for generating a signal indicative of excessive deceleration if a sensed deceleration exceeds the threshold value.
The means for changing the torque reference input signal to a low or a negative value may comprise means for modifying or replacing the torque reference input signal upon receipt of the above signal indicative of excessive deceleration. In a preferred embodiment, the means for inputting a torque reference signal to the controller comprises (a) a signal summing means operative to receive a normal torque reference signal and an emergency torque reference signal and output the sum of the signals to the controller, and (b) switch means operative to input the emergency torque reference signal to the signal summing means only when the switch means receives the above signal indicative of excessive deceleration.
The invention also embraces a method of emergency control of a power plant in which an electric motor drives a propeller through a mechanical drive train, the method comprising the steps of:
Further aspects of the invention will be apparent from the following description and claims.
Exemplary embodiments of the invention will now be described with reference to the accompanying drawings, in which:
Referring to
The torque applied by the electric motor 30 to the drive train 32 during normal operation of the system is set by a known type of vector control performed by the controller 33. The system uses encoder shaft position sensing, as known, to effect vector control of the motor, also known in itself. Motor shaft position information from an encoder E is used to facilitate high-bandwidth field-oriented control in the vector controller 33, which in turn regulates the torque applied by the motor 30. Hence, a motor shaft position signal S is produce by a shaft position encoder E (known per se) and input to the controller 33 together with a normal reference signal RN which represents a desired torque to be produced by the motor. These inputs are utilized by the controller to produce output signals V for driving the above-mentioned PWM converter, by means of which the motor's output torque is varied.
At all times during normal operation of the propulsion system, the rate of change of motor speed is monitored by a monitor subsystem 34. In software or otherwise, the shaft position signal S from the encoder E is differentiated twice (d/dt2). The first differentiation produces a shaft rotational speed signal R, which may be used later as described below, and the second differentiation produces a shaft rotational acceleration/deceleration signal A. This signal A is fed to a comparator 35, where it is compared with a deceleration threshold signal AT. AT represents an excessive deceleration of the motor speed, indicative of an external obstruction or fouling of the propeller, such as by the propeller striking a large block of ice. If comparator 35 detects that deceleration threshold AT has been exceeded, the comparator triggers (e.g., by means of a software or hardware switch 36) the input of an emergency torque reference signal RE to a summing junction 37. Summing of the signal RE with the normal torque reference signal RN produces a modified torque reference signal RM.
Alternatively, the emergency torque reference signal RE may simply temporarily replace the normal reference signal RN, making RM=RE.
By setting the emergency torque reference RE, to an appropriate low or negative value, the transfer of rotational stored energy into the obstruction can be reduced. For example, if on detection of the obstruction the emergency torque reference RE (or RM if modified by summing with RN) is set to maximum deceleration, the energy transferred to the obstruction will be minimized. Effectively, the system achieves a synthetic reduction of drive train inertia.
When the shaft stops, or if the ice load is removed, then the fast rate of fall in speed will cease and normal operation can continue.
It should be realized that AT or indeed RE need not be a fixed values. For instance, RE may be a torque/time characteristic and both or either may be programmable to vary as functions of one or more characteristics of the drive, such as shaft rotational speed immediately before the activating deceleration. In this way, one could achieve the effect that the greater the speed of the motor prior to the event, the greater the reverse torque applied by the motor and hence the greater the retardation applied to the motor end of the propeller drive train to act against the deceleration shock produced by fouling of the propeller.
In the above system, the control of the motor's torque can be either open loop or closed loop.
A simulation has found that the control method of the invention reduces the mechanical stress levels in the propeller shaft by typically 2:1. One of the advantages of the invention is that it will allow faster motors to be used, without danger of damaging the drive train. Note that high-speed motors are lower in cost than slow-speed motors. Lower cost gears and shafts can also be used.
The method also allows higher torque to be used at low speeds for slowly applied loads.
Number | Date | Country | Kind |
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0406767.4 | Mar 2004 | GB | national |
0407997.6 | Apr 2004 | GB | national |
Number | Name | Date | Kind |
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3478622 | Reid | Nov 1969 | A |
3618719 | Marland | Nov 1971 | A |
5647780 | Hosoi | Jul 1997 | A |
6726588 | Weisz | Apr 2004 | B2 |
Number | Date | Country |
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32 02 988 | Aug 1983 | DE |
102 17 887 | Nov 2003 | DE |
2 082 533 | Mar 1982 | GB |
9-301275 | Nov 1997 | JP |
Number | Date | Country | |
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20050221697 A1 | Oct 2005 | US |