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AU2006284523B2 - Stabilising means - Google Patents

Stabilising means Download PDF

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Publication number
AU2006284523B2
AU2006284523B2 AU2006284523A AU2006284523A AU2006284523B2 AU 2006284523 B2 AU2006284523 B2 AU 2006284523B2 AU 2006284523 A AU2006284523 A AU 2006284523A AU 2006284523 A AU2006284523 A AU 2006284523A AU 2006284523 B2 AU2006284523 B2 AU 2006284523B2
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AU
Australia
Prior art keywords
cradle
vehicle
rotor
axis
stabilising means
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AU2006284523A
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AU2006284523A1 (en
Inventor
Antony Richard Elms
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Veem Ltd
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Veem Ltd
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Filing date
Publication date
Priority claimed from AU2005904539A external-priority patent/AU2005904539A0/en
Application filed by Veem Ltd filed Critical Veem Ltd
Priority to AU2006284523A priority Critical patent/AU2006284523B2/en
Priority claimed from PCT/AU2006/001214 external-priority patent/WO2007022575A1/en
Publication of AU2006284523A1 publication Critical patent/AU2006284523A1/en
Application granted granted Critical
Publication of AU2006284523B2 publication Critical patent/AU2006284523B2/en
Assigned to Ship Dynamics Group Pty Ltd reassignment Ship Dynamics Group Pty Ltd Request for Assignment Assignors: TECHNOLOGY INVESTMENT COMPANY PTY LTD
Assigned to J2 Technologies Pty Ltd reassignment J2 Technologies Pty Ltd Request for Assignment Assignors: Ship Dynamics Group Pty Ltd
Assigned to Veem Limited reassignment Veem Limited Request for Assignment Assignors: J2 Technologies Pty Ltd
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Description

"Stabilising Means" Field of the Invention 5 This invention relates to a stabilising means which can be utilised with mobile platforms such as vehicles and throughout the specification the term "vehicle" shall be taken to comprise any form of waterborne, land borne or airborne vehicle capable of moving through the relevant medium and furthermore shall be taken to include platforms which are substantially stationary and are essentially suspended 10 such as those floating on water, those that are airborne and even those in outer space where it is desired to maintain the platform substantially stationary. An example of a stationary platform is a floating drilling platform which is maintained in station over a drilling site. 15 A particular application of the invention relates to a stabilising means which can be utilised with waterborne vessels. The stabilising means according to the invention utilises a gyroscopic system. Gyroscopic stabilising systems have been proposed in the past but because of their mass and the space required to accommodate them they have generally been limited to use with large vessels. 20 However, more recently, the availability of rolling element bearings and closed loop control devices have also reduced cost and possibly size. The orientation adopted limits the axial bearing load that would otherwise be required to support the rotor weight. It is the axial load that limits the speed of the rotor and hence the weight of rotor required. Examples of arrangements which have been proposed in 25 the past are disclosed in GB 243316, US 5628267, GB 581776, GB 1315119. Some arrangements which have been proposed in the past have provided that the gyroscopic arrangement actively cooperates with a set of foils and/or the rudder in order to control movement of the vessel while other arrangements comprise 30 passive arrangements to control the rolling of the vehicle. The above discussion of the background to the invention is intended to facilitate an understanding of the present invention only. It should be appreciated that the discussion is not an acknowledgement or admission that any of the material referred to was published, known or part of the common general knowledge of the person skilled in the art in any jurisdiction as at the priority date of the invention. Summary of the Invention The present invention seeks to overcome, or at least ameliorate, one or more of 5 the deficiencies of the prior art mentioned above, or to provide the consumer with a useful or commercial choice. Advantages of the present invention will become apparent from the following description, taken in connection with the accompanying drawings, wherein, by way of illustration and example, preferred embodiment(s) of the present invention 10 is disclosed. Throughout the specification the term "axis of stabilisation" shall be taken to include the axis about which the precession forces created by the movement of the rotor are not to be active. In the case of a vehicle which is expected to undergo movement in a direction the "stabilisation axis" is the direction of motion. 15 According to a first aspect of the present invention, there is provided a vehicle stabilising means comprising a pair of cradles, each cradle supported from a mounting such that the cradles are in a generally side by side relationship with respect to each other, each cradle supporting a rotor by a pair of spaced supports, the rotor rotatably supported by the supports to rotate about a first axis, a drive 20 supported from the cradle and coupled to the respective rotor enabling the rotor to rotate about the respective first axis at a substantially constant angular velocity, the rotation of the rotors being in opposite directions, each cradle rotatably supported from the mounting through a sewing bearing to be rotatable around a second axis which is perpendicular to the first axis of rotation of the rotor, the 25 mounting intended in use to be fixed to the vehicle such that when the rotors are rotating the mean orientation of the first and second axes are substantially perpendicular to the direction of the axis of stabilisation. According to a preferred feature of the invention, vehicle stabilising means further comprises a control means including a control device interconnecting the cradles.
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According to a preferred feature of the invention in use the cradles are positioned to lie transversely side by side within the vehicle. According to a preferred feature of the invention, the mean orientation of the first axes are substantially co-linear. 5 According to a preferred feature of the invention in use the cradles are positioned longitudinally side by side within the vehicle with respect to the fore and aft axis of the vehicle. According to a preferred feature of the invention the first axes are substantially parallel. 10 According to a preferred feature of the invention in use the cradles are located in their side by side relationship along a mounting axis located at any position between the fore and aft axis of the vehicle and transverse to the fore and aft axis. According to a preferred feature of the invention the cradles extend from the mounting to opposite sides of the mounting. 15 According to a preferred feature of the invention the control means is adapted to cause equal and opposite precession of the cradles with respect to each other on a precession moment being applied to one or both of the rotors. According to a preferred feature of the invention the control means comprises a gearing interconnection between the cradles. 20 According to a preferred feature of the invention the gearing connection comprises a gear element on each cradle which is at least partially circular, said gear elements being meshingly interconnected. According to a preferred feature of the invention at least one cradle is associated with a. second drive means adapted to overcome inertial and/or frictional forces 25 applied to the cradle on a precession moment being applied to the cradle by the rotor.
-4 According to a preferred feature of the invention the second drive means comprises at a gear meshingly engaged with the gear element of at least one cradle and driven from a second drive, said second drive being controlled from a controller adapted to sense the induction and variation of the precession moment 5 applied by the rotor to the cradle and to cause the second drive to cause corresponding movement of the cradle to overcome the inertia thereof. According to an embodiment the gear comprises a pinion gear. According to another embodiment the gear comprises a worm gear. According to a further embodiment the gear comprises a helical gear. 10 According to a preferred feature of the invention wherein the second drive is adapted to be able to apply a damping force to the cradle as result of activation from the controller. According to a preferred feature of the invention the control means comprises a pulley cord extending around and between each cradle. 15 According to a preferred feature of the invention the cord can be selected from any one or combination of a pulley belt, chain cable and a flexible elongate element. According to a preferred feature of the invention at least one cradle is associated with a second drive means adapted to overcome inertial and/or frictional forces 20 applied to the cradle on a precession moment being applied to the cradle by the rotor. According to a preferred feature of the invention the control means comprises a fluid drive interconnecting each cradle. According to a preferred feature of the invention at least one cradle is associated 25 with a braking means adapted to provide a braking torque to the cradles on rotation of the cradles beyond a predetermined position displaced angularly from the mean position of the cradle.
-- b According to a preferred feature of the invention the braking means comprises the second drive means. According to a preferred feature of the invention the braking means is adapted to provide a braking torque to the cradle on the acceleration or deceleration of 5 rotation of the cradle, as a result of the precession moment being applied to the cradle, exceeding a desired limit. According to a preferred feature of the invention the braking means comprises one or more linear actuators connected to one or more cradles. According to a preferred feature of the invention the cradle is supported from the 10 mounting by a substantially co-planar slewing bearing capable of supporting radial, axial and tilting loads from a single bearing assembly lying substantially in a single plane. According to a second aspect the present invention, there is provided a vehicle stabilising means comprising a cradle supported from mounting, a rotor supported 15 from the cradle by a pair of spaced supports to be rotatably supported by the supports for rotation about a first axis, a drive coupled to the rotor enabling the rotor to rotate about the first axis at a substantially constant angular velocity, the cradle rotatably supported from the mounting through a slewing bearing assembly to be rotatable around a second axis which is perpendicular to the first axis of 20 rotation of the rotor, the mounting intended in use to be fixed to the vehicle such that when the rotor is rotating the mean orientation of the first and second axes are substantially perpendicular to the direction of the axis of stabilisation. According to a preferred feature of the invention the cradle is associated with an drive means adapted to overcome inertial and/or frictional forces applied to the 25 cradle on a precession moment being applied to the cradle by the rotor. According to a preferred feature of the invention the cradle is supported from the mounting by a substantially co-planar slowing bearing capable of supporting radial, axial and tilting loads from a single bearing assembly lying substantially in a single plane.
- b According to a preferred feature of the invention in use the second axes substantially comprises an upright axis of the vehicle. According to a third aspect the present invention, there is provided a vehicle having a vehicle stabilising means of the form as described above. 5 According to a preferred feature of the invention the vehicle comprises a waterborne vessel. According to a preferred feature of the invention the one side of the mounting is uppermost. According to a preferred feature of the invention one side of the mounting is 10 lowermost. According to a preferred feature of the invention wherein the one side of the mounting is generally upright. According to a preferred feature of the invention wherein the one side of the mounting is inclined. 15 Brief Description of the Drawings Embodiments of the present invention will now be described in a non-limiting way, with reference to the accompanying description and drawings of which; Figure 1 is an isometric view of stabilising means according to the first embodiment; 20 Figure 2 is an isometric view of the stabilising means according to the first embodiment with the rotor covers removed; Figure 3 is a side elevation of a stabilising means according to the first embodiment; Figure 4 is an end elevation of a stabilising means according to the first embodiment; Figure 5 is a sectional side elevation of the first embodiment along the line 5-5 of Figure 4; Figure 6 is an isometric view of stabilising means according to the second 5 embodiment; Figure 7 is an isometric view of the stabilising means according to the second embodiment with the rotor covers removed; Figure 8 is a side elevation of a stabilising means according to the second embodiment; 10 Figure 9 is an end elevation of a stabilising means according to the second embodiment; Figure 10 is a sectional side elevation of the second embodiment along the line 5 15 5 of Figure 9; Figure 11 is an isometric view of a third embodiment of the invention; Figure 12 is a schematic plan view of a fourth embodiment of the invention; and 20 Figure 13 is a plan view of a fifth embodiment of the invention. Best Mode(s) for Carrying Out the Invention 25 The embodiments each relate to a stabilising means which is intended for use is association with a motor yacht, commercial transport vessel or military vessel. In the past the application of a stabilising means utilising a gyroscopic system has been impractical in motor yachts because of the mass of the system and the volume occupied by such systems and the difficulty of servicing the rotors of such 30 systems. In motor yachts, a large proportion of their operating time is spent stationary or moving at low speeds and under these conditions the rolling action which can be applied to the vessel by sea conditions can be very undesirable. Therefore it is desirable to minimise the amount of rolling action applied to a vessel. 5 The first embodiment as shown at Figures 1 to 5 comprises a stabilising means which is intended for installation in a motor yacht, commercial transport vessel or military vessel where the stabilisation axis is parallel to the fore and aft axis of the vessel. The stabilising means comprises a pair of housings 11 and 13 and each housing is provided with a rotor cover 15 supported from a base 17. Each rotor 10 covers encloses a rotor 19 having a pair of trunnions which are rotatably supported from a cradle 23. The cradle 23 is comprises a pair of upstanding supports 25 supported from a base 31. The supports 25 are positioned in spaced relation across the base 31 of the cradle and are located to each side of the rotor 19. The upper end of each upstanding support is provided with a journal 27 which 15 accommodates appropriate bearings which receive the trunnions 21 of the rotor to enable free rotation of the rotors on the upstanding supports 25 about first axes which are central to each rotor. Each rotor is associated with a hydraulic motor 29 supported from the upstanding supports 25 to cause the rotation of the rotors on the cradle 23. In the case of the first embodiment each base 31 is supported from 20 a mounting 17 and the mountings are interconnected in a side by side relationship such that under operation the mean orientation of the first axes of rotation of the rotors are substantially co-linear. The drive which is provided by each of the motors 29 will cause rotation of each of the rotors about the first axes at substantially equal and constant angular speed however the rotation of the rotors 25 are in opposite directions. Each cradle is supported from the respective mounting 17 to be able to rotate on the mounting about a second axis of rotation which is perpendicular to the respective first axis of the rotor and intersects the first axis of the respective rotor 30 19. The rotational support for each base on the mounting is provided by a slewing bearing 33. The mountings 17 are fixed in a side-by-side relationship such that the first axes of rotation of the rotor 19 are collinear and the embodiment is positioned within the vessel such that the first axes are abeam of the hull of the vessel.
Each of the cradles 23 are interconnected by a pair of pulleys belts 35 which each pass around both cradles but which also crossover between the cradles. As a result of the arrangement of the pulleys rotation of one cradle will cause the opposite and equal rotation of the other cradle. 5 In addition each cradle is associated with an second drive (not shown) which is associated with a sensor and an associated controller which is able to detect when the cradle may be subjected to a precessional torque applied to the cradle by the respective rotor 19 and provide an indication of the magnitude of the 10 torque. The sensor may itself incorporate a gyroscope. The operation of the second drive is to overcome the inertia! and/or friction forces which are applied to the cradle on application of a precessional torque from the respective rotor 19 and in order that the movement of the cradle is immediately responsive to the application of any such precessional torque, and to overcome the momentum 15 contained in the cradle when the influence of the precessional forces has dissipated. In addition each cradle is associated with a braking means (not shown) which is adapted to apply a braking torque to the cradle on the precessional rotation of the 20 cradle causing movement beyond a predetermined position angularly spaced from the neutral position of the cradle, and/or is caused to move at a rate which is greater than desired. The second embodiment as shown at Figures 6 to 10 (the same reference 25 numerals are used as those used in relation to the first embodiment for corresponding components) comprises a stabilising means which is intended for installation in a motor yacht, commercial transport vessel or military vessel where the stabilisation axis is parallel to the fore and aft axis of the vessel. The stabilising means comprises a housing 11 which encloses a pair of rotors 19 each 30 having a pair of trunnions which are rotatably supported from their own cradle 23. The cradles 23 each comprises a pair of upstanding supports 25 supported from a base 31. The supports 25 are positioned in spaced relation across the base 31 of the cradle and are located to each side of the rotor 19. The upper end of each upstanding support is provided with a journal 27 which accommodates - -Iu appropriate bearings which receive the trunnions 21 of the rotor to enable free rotation of the rotors on the upstanding supports 25 about first axes which are central to each rotor. Each rotor is associated with a hydraulic motor 29 supported from the upstanding supports 25 and connected to the respective rotor through a 5 pulley drive to cause the rotation of the rotor on the cradle 23. In the case of the second embodiment each base 31 is supported from a common mounting 17 in a side by side relationship such that when operating the mean orientation of the first axes of rotation of the rotors are substantially co-linear. The drive which is provided by each of the motors 29 will cause rotation of each of the rotors about 10 the first axes at substantially equal and constant angular speed however the rotation of the rotors are in opposite directions. Each cradle is supported from the mounting to be able to rotate about a second axis of rotation which is perpendicular to the respective first axis of the rotor and 15 intersects the first axis of the respective rotor 19. The rotational support for each base on the mounting is provided by a slewing bearing 33 between the respective base and the mounting. The cradles are fixed in a side-by-side relationship such that when operating the mean orientation of the first axes of rotation of the rotor 19 are collinear and the embodiment is located within the vessel such that the 20 mean orientation of the first axes are abeam of the hull of the vessel. The base of each of the cradles are provided with a ring gear 41 which is concentric with the second axis and the ring gears of the cradles 23 are meshingly interconnected. As a result of the meshing interengagement of the cradles 25 through the ring gears the rotation of one cradle will cause the opposite and equal rotation of the other cradle. In addition each cradle is associated with a second drive 43 which is associated with a sensor and an associated controller which is able to detect when the cradle 30 may be subjected to a precessional torque applied to the cradle by the respective rotor 19 and provide an indication of the magnitude of the torque. The sensor may itself incorporate a gyroscope. The second drive is operatively connected to a spur gear 45 meshingly engaged with one of the ring gears whereby on activation of the second drive the spur gear is driven to cause rotation of the cradles. The - 1i operation of the second drive is to overcome the inertial and/or friction forces which are applied to the cradles on application of a precessional torque from the respective rotor 19 and in order that the movement of the cradle is immediately responsive to the application of any such precessional torque. In addition the 5 second drive can serve as a braking means to control the continued rotation of the cradles under the influence of the momentum induced into the cradle with precession of the rotors and on the cessation of the application of the precessional forces to the cradle. In addition each cradle is associated with a braking means (not shown) which is 10 adapted to apply a braking torque to the cradle on the precessional rotation of the cradle causing movement beyond a predetermined position angularly spaced from the neutral position of the cradle, and/or is caused to move at a rate which is greater than desired. The braking means serves to supplement the braking that is applied by the spur gear 45. 15 The third embodiment as shown at Figure 11 comprises a single rotor which corresponds to one rotor of the second embodiment and where vessel where the stabilisation axis is parallel to the fore and aft axis of the vessel. The mean orientation of the first axis of the rotor when operating is substantially 20 perpendicular to the stabilisation axis. The fourth embodiment as shown at Figure 12 is a variation of the second embodiment in that while the rotors 19 are located in a side by side relationship along a central fore and aft axis of the hull of the vessel the first axes of rotation of 25 the rotors are parallel and directed abeam across the vessel. The stabilisation axis is parallel to the fore and aft axis of the vessel. The fifth embodiment as shown at Figure 13 is a variation of the second embodiment in that while the rotors 19 are located in a side by side relationship 30 they are mounted to a common mounting 17 such that the cradles are supported from opposite sides of the common mounting and such that the first axes of rotation of the rotors are parallel.
- -IZ According to a sixth embodiment of the invention the second axes (being the axes of rotation of the cradle on the respective base) are directed abeam and the first axes of rotation (being the axes of rotation) of the rotors are upright with respect to the hull of the vessel. 5 According to an alternative embodiment of each of the above embodiments the rotors are driven by an electric motor. It will be understood that the mounting of each of the embodiments can be positioned to be lowermost or uppermost or at any angular position therebetween 10 around the stabilisation axis. When each of the above embodiments described are applied to a waterborne vessel, where the stabilisation axis comprises an axis which is parallel to the fore and aft axis of the vessel, the use of a pair of rotors which are rotating in opposite 15 directions but at substantially equal angular speed ensures that in the event of the vessel being subjected to a rolling action about the fore-aft axis of the vessel the rolling action will be in part negated by the corresponding precession of the rotors. In addition in the event of the hull under-going a rotational movement about an upright axis (i.e. turning) the torque generated will be equal and opposite between 20 rotors is thus neutralised. In addition in the event of the hull undergoing a rotational movement about a horizontal axis that is perpendicular to the stabilisation axis the resultant precessional movement of the rotors will counteract each other to have no substantial effect on such rotation or stabilisation in the other axis. 25 The configuration of the each of the embodiments provides a stabilisation means which differs from all of the known prior art in that it has a reduced profile since the support for the rotors is to one side of the axes of rotation of the rotors. Furthermore this arrangement provides for easier servicing of the rotors and 30 replacement of the rotors and motors. As a result the stabilisers according to the embodiment can have application in smaller vessels than has been the case for prior art stabilisers.
- 1I3 Throughout the specification, unless the context requires otherwise, the word "comprise" or variations such as "comprises" or "comprising", will be understood to imply the inclusion of a stated integer or group of integers but not the exclusion of any other integer or group of integers. 5 Furthermore, throughout the specification, unless the context requires otherwise, the word "include" or variations such as "includes" or "including", will be understood to imply the inclusion of a stated integer or group of integers but not the exclusion of any other integer or group of integers. Additionally, throughout the specification, unless the context requires otherwise, 10 the words "substantially' or "about" will be understood to not be limited to the value for the range qualified by the terms. It should be appreciated that the scope of the invention is not limited to the particular arrangement or application of the embodiments described above. 15 Modifications and variations such as would be apparent to a skilled addressee are deemed to be within the scope of the present invention.

Claims (29)

1. A vehicle stabilising means comprising a pair of cradles, each cradle supported from a mounting such that the cradles are in a generally side by side relationship with respect to each other, each cradle supporting a rotor by a pair of spaced supports, the rotor rotatably supported by the supports to rotate about a first axis, a drive supported from the cradle and coupled to the respective rotor enabling the rotor to rotate about the respective first axis at a substantially constant angular velocity, the rotation of the rotors being in opposite directions, each cradle rotatably supported from the mounting through a sewing bearing to be rotatable around a second axis which is perpendicular to the first axis of rotation of the rotor, the mounting intended in use to be fixed to the vehicle such that when the rotors are rotating the mean orientation of the first and second axes are substantially perpendicular to the direction of the axis of stabilisation.
2. A vehicle stabilising means as claimed at claim 1, the further comprising a control means including a control drive interconnecting the cradles.
3. A vehicle stabilising means as claimed at claim 1 or 2 wherein in use the cradles are positioned to lie transversely side by side within the vehicle.
4. A vehicle stabilising means as claimed at claim 3 wherein the mean orientation of the first axes are substantially co-linear.
5. A vehicle stabilising means as claimed at claim 1 or 2 wherein in use the cradles are positioned longitudinally side by side within the vehicle with respect to the fore and aft axis of the vehicle.
6. A vehicle stabilising means as claimed at claim 5 wherein the mean orientation of the first axes are substantially parallel. -15'
7. A vehicle stabilising means as claimed at claim 1 or 2 wherein in use the cradles are located in their side by side relationship along a mounting axis located at any position between the fore and aft axis of the vehicle and transverse to the fore and aft axis.
8. A vehicle stabilising means as claimed at claim 1, or 5 or 6, or 7 wherein the cradles extend from the mounting to opposite sides of the mounting.
9. A vehicle stabilising means as claimed at any one of claims 2 to 7 when dependent from claim 2 wherein the control means is adapted to cause equal and opposite precession of the cradles with respect to each other on a precession moment being applied to one or both of the rotors.
10. A vehicle stabilising means as claimed at claim 9 wherein the control means comprises a gearing interconnection between the cradles.
11. A vehicle stabilising means as claimed at claim 10 wherein the gearing connection comprises a gear element on each cradle which is at least partially circular, said gear elements being meshingly interconnected.
12. A vehicle stabilising means as claimed at any one of claims 1 to 11 wherein at least one cradle is associated with a second drive means adapted to overcome inertial and/or frictional forces applied to the cradle on a precession moment being applied to the cradle by the rotor.
13. A vehicle stabilising means as claimed at claim 12 when dependent from claim 11 wherein the second drive means comprises at a gear meshingly engaged with the gear element of at least one cradle and driven from a second drive, said second drive being controlled from a controller adapted to sense the induction and variation of the precession moment applied by the rotor to the cradle and to cause the second drive to cause corresponding movement of the cradle to overcome the inertia thereof.
14. A vehicle stabilising means as claimed at claim 13 wherein the gear comprises a pinion gear, a worm gear, or a helical gear. - Int
15. A vehicle stabilising means as claimed at any one of claims 12 to 14 wherein the second drive is adapted to be able to a apply a damping force to the cradle as result of activation from the controller
16. A vehicle stabilising means as claimed at any one of claims 2 to 15 when dependent from claim 2 wherein the control means comprises a pulley cord extending around and between each cradle.
17. A vehicle stabilising means as claimed at claim 16 wherein the cord can be selected from any one or combination of a pulley belt, chain cable and a flexible elongate element.
18. A vehicle stabilising means as claimed at any claim 16 or 17 wherein at least one cradle is associated with a second drive means adapted to overcome inertial and/or frictional forces applied to the cradle on a precession moment being applied to the cradle by the rotor.
19. A vehicle stabilising means as claimed at any one of claims 2 to 18 when dependent from claim 2 wherein the control means comprises a fluid drive drivingly interconnecting the cradles.
20. A vehicle stabilising means as claimed at any one of claims 9 to 19 wherein at least one cradle is associated with a braking means adapted to provide a braking torque to the cradles on rotation of the cradles beyond a predetermined position displaced angularly from the mean position of the cradle.
21. A vehicle stabilising means as claimed at claim 20 when dependent from any one of claims 12, 13 and 19 wherein the braking means comprises the second drive means.
22. A vehicle stabilising means as claimed at claim 20 or 21 wherein the braking means is adapted to provide a braking torque to the cradle on the acceleration or deceleration of rotation of the cradle, as a result of the precession moment being applied to the cradle, exceeding a desired limit. - If
23. A vehicle stabilising means as claimed at any one of claims 20 to 22 wherein the braking means comprises one or more linear actuators connected to one or more cradles.
24. A vehicle stabilising means comprising a cradle supported from a mounting, a rotor supported from the cradle by a pair of spaced supports to be rotatably supported by the supports for rotation about a first axis, a drive coupled to the rotor enabling the rotor to rotate about the first axis at a substantially constant angular velocity, the cradle rotatably supported from the mounting through a slewing bearing assembly to be rotatable around a second axis which is perpendicular to the first axis of rotation of the rotor, the mounting intended in use to be fixed to the vehicle such that when the rotor is rotating the mean orientation of the first and second axes are substantially perpendicular to the direction of the axis of stabilisation.
25. A vehicle stabilising means as claimed at claim 24 wherein the cradle is associated with a second drive means adapted to overcome inertial and/or frictional forces applied to the cradle on a precession moment being applied to the cradle by the rotor.
26. A vehicle stabilising means as claimed at any one of the preceding claims wherein the cradle is supported from the mounting by a substantially co planar slowing bearing capable of supporting radial, axial and tilting loads from a single bearing assembly lying substantially in a single plane,
27. A vehicle stabilising means as claimed at claim 24 or 25 wherein in use the second axes substantially comprises an upright axis of the vehicle.
28. A vehicle having a vehicle stabilising means of the form as claimed in any one of the preceding claims.
29. A vehicle as claimed at claim 28 wherein the vehicle comprises a waterborne vessel.
AU2006284523A 2005-08-22 2006-08-22 Stabilising means Active AU2006284523B2 (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
AU2006284523A AU2006284523B2 (en) 2005-08-22 2006-08-22 Stabilising means

Applications Claiming Priority (4)

Application Number Priority Date Filing Date Title
AU2005904539A AU2005904539A0 (en) 2005-08-22 Stabilising Means
AU2005904539 2005-08-22
AU2006284523A AU2006284523B2 (en) 2005-08-22 2006-08-22 Stabilising means
PCT/AU2006/001214 WO2007022575A1 (en) 2005-08-22 2006-08-22 Stabilising means

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AU2006284523A1 AU2006284523A1 (en) 2007-03-01
AU2006284523B2 true AU2006284523B2 (en) 2010-08-05

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Families Citing this family (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN107472476A (en) * 2017-08-09 2017-12-15 江苏华阳重工股份有限公司 Plane gyro-precession type ship gyro, which subtracts, to be shaken

Citations (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JPH08297027A (en) * 1995-04-27 1996-11-12 Komatsu Ltd Damping device of running working vehicle
US5628267A (en) * 1993-11-01 1997-05-13 Mitsubishi Jukogyo Kabushiki Kaisha Oscillation suppression device and ship provided with the same
US20050072726A1 (en) * 2002-01-09 2005-04-07 Wolfgang Laub Filter for phase separation

Patent Citations (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US5628267A (en) * 1993-11-01 1997-05-13 Mitsubishi Jukogyo Kabushiki Kaisha Oscillation suppression device and ship provided with the same
JPH08297027A (en) * 1995-04-27 1996-11-12 Komatsu Ltd Damping device of running working vehicle
US20050072726A1 (en) * 2002-01-09 2005-04-07 Wolfgang Laub Filter for phase separation

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