Method and a control arrangement for controlling vibrations of a propulsion unit of a vessel

The invention claimed is: 1. A method for controlling vibrations of a propulsion unit of a vessel, the propulsion unit comprising: a frame construction having an upper portion and a lower portion, the upper portion forming an outwards from a hull of the vessel protruding support arm, the lower portion forming a longitudinal compartment having a first end and a second opposite end, a propeller shaft being positioned within the lower portion of the frame construction, at least one propeller being attached to the propeller shaft, a first electric motor driving the propeller shaft, the method comprising: measuring vibrations of the propulsion unit with at least one measuring device, forming a first auxiliary torque control signal based on the measured vibration signal, adding the first auxiliary torque control signal to a first torque control signal produced by a first torque controller of the first electric motor, the first auxiliary torque control signal acting against the measured vibrations in order to attenuate said vibrations. 2. The method according to claim 1 , further comprising measuring the vibrations of the propulsion unit in a longitudinal direction of the vessel and by producing with the first auxiliary torque signal a counteracting thrust with the at least one propeller, said counteracting thrust acting in an opposite direction in relation to the longitudinal vibrations of the propulsion unit, whereby said vibrations are attenuated by the counteracting thrust. 3. The method according to claim 1 , further comprising measuring the vibrations of the propulsion unit in a transverse direction of the vessel and by producing with the first auxiliary torque signal a counteracting bending moment by utilizing the rotation inertia of the first electric motor and the propeller, said counteracting bending moment acting in an opposite direction in relation to the transverse vibrations of the propulsion unit, whereby said vibrations are attenuated by the counteracting bending moment. 4. The method according to claim 2 , further comprising measuring vibrations of the propulsion unit in the longitudinal direction of the vessel and in the transverse direction of the vessel simultaneously and producing the counteracting thrust and the counteracting bending moment simultaneously. 5. The method according to claim 1 , wherein the propulsion unit further comprises: a rotation member within the hull of the vessel, said rotation member being connected to an upper end of the upper portion of the frame construction, and at least one second electric motor being connected to the rotation member, the propulsion unit being rotatable around a centre axis of rotation via the rotation member with at least one second electric motor, the method further comprising: measuring vibrations of the propulsion unit in a rotational direction of the propulsion unit with at least one measuring device, forming a second auxiliary torque control signal based on the measured vibration signal, adding the second auxiliary torque control signal to a second torque control signal produced by a second torque controller of the second electric motor, the second auxiliary torque control signal acting against the measured vibrations in order to attenuate said vibrations. 6. The method according to claim 1 , further comprising rating the first auxiliary torque control signal to a value in the range of 1 to 20% of the maximum torque value produced by the first torque controller of the first electric motor and by rating the second auxiliary torque control signal to a value in the range of 1 to 20% of the maximum torque value produced by the second torque controller of the second electric motor. 7. The method according to claim 1 , further comprising rating the first auxiliary torque control signal to a value in the range of 1 to 3% of the maximum torque value produced by the first torque controller of the first electric motor and by rating the second auxiliary torque control signal to a value in the range of 1 to 3% of the maximum torque value produced by the second torque controller of the second electric motor. 8. The method according to claim 1 , further comprising using at least one measuring device for measuring longitudinal vibration of the propulsion unit and by using at least one measuring device for measuring transverse vibration of the propulsion unit and positioning said measuring devices on the propeller shaft level within the propulsion unit. 9. The method according to claim 1 , further comprising using at least one measuring device for measuring rotational vibration of the propulsion unit and positioning said at least one measuring device on the propeller shaft level within the propulsion unit or on a slewing bearing level within the vessel. 10. A control arrangement for controlling vibrations of a propulsion unit of a vessel, the propulsion unit comprising: a frame construction having an upper portion and a lower portion, the upper portion forming an outwards from a hull of the vessel protruding support arm, the lower portion forming a longitudinal compartment having a first end and a second opposite end, a propeller shaft being positioned within the lower portion of the frame construction, at least one propeller being attached to the propeller shaft, a first electric motor driving the propeller shaft, the control arrangement comprising: at least one measuring device for measuring vibrations of the propulsion unit, a first torque controller for producing a torque control signal to the first electric motor, a first additional torque controller receiving as an input signal measured vibrations from the at least one measuring device, a first active vibration controller for producing a first auxiliary torque control signal based on the measured vibration signals, whereby the first auxiliary torque control signal is added to a first torque control signal produced by the first torque controller of the first electric motor, the first auxiliary torque control signal acting against the measured vibrations in order to attenuate said vibrations. 11. The control arrangement according to claim 10 , wherein the arrangement comprises at least one measuring device measuring vibrations of the propulsion unit in a longitudinal direction of the vessel, whereby the first auxiliary torque signal produces a counteracting thrust with the at least one propeller, said counteracting thrust acting in an opposite direction in relation to the longitudinal vibrations of the propulsion unit, whereby said vibrations are attenuated by the counteracting thrust. 12. The control arrangement according to claim 10 , wherein the arrangement comprises at least one measuring device measuring vibrations of the propulsion unit in a transverse direction of the vessel, whereby the first auxiliary torque signal produces a counteracting bending moment by utilizing the rotation inertia of the first electric motor and the propeller, said counteracting bending moment acting in an opposite direction in relation to the transverse vibrations of the propulsion unit, whereby said vibrations are attenuated by the counteracting bending moment. 13. The control arrangement according to claim 11 , wherein the arrangement comprises at least one measuring device measuring vibrations of the propulsion unit in a longitudinal direction of the vessel and at least one measuring device measuring vibrations of the propulsion unit in a transverse direction of the vessel, whereby measurement of vibrations of the propulsion unit in the longitudinal direction of the vessel and in the transverse direction of the vessel is done simultaneously and the