Drive system for a propeller

Abstract

The invention relates to a drive system, and method of forming the same, for a craft in water, said drive system comprising a drive means, one or more shafts which are provided in connection with the drive means via one or more gear assemblies and at least one of said shafts having a free end with location means to allow the same to be located with a propeller of the said craft to impart rotational drive to the propeller. The location means are at least partially located within a port in the body of the propeller and intermediate said location means and the walls of the said port there is provided a substantially non-conductive deformable material sleeve which separates the propeller body from the said shaft and retains the propeller body in drive engagement with the location means. The provision of the sleeve allows the electrical isolation of the sleeve and propeller, allows a more robust connection between the propeller and drive means and reduces the impact of vibration on the operation and efficiency of the propeller.

Claims

1. A drive apparatus for a craft in water, said drive apparatus comprising a drive means, one or more shafts which are provided in connection with the drive means via one or more gear assemblies and at least one of said shafts having a free end with location means to allow the same to be located with a propeller of the said craft to impart rotational drive to the propeller and wherein said location means are at least partially located within a port in the body of the propeller and intermediate said location means and the walls of the said port there is provided an at least partially deformable sleeve which separates the propeller body from the said shaft and retains the propeller body with the location means, the sleeve having a closed end.

2. Apparatus according to claim 1 wherein the sleeve in cross section is provided with annular walls.

3. Apparatus according to claim 1 wherein the sleeve is formed such that the thickness of an annular wall varies along the length of the sleeve.

4. Apparatus according to claim 1 wherein a first end of the sleeve which lies at, or adjacent to the opening into the port has a narrower annular wall thickness than a further portion of said annular wall.

5. Apparatus according to claim 1 wherein there is provided a casing which is in drive engagement with the location means and is located in the port of the propeller body to allow drive to be imparted from the shaft to the propeller.

6. Apparatus according to claim 5 wherein the shape of the sleeve located against the wall of the casing is such as to allow drive to be imparted to the sleeve and hence to the body of the propeller.

7. Apparatus according to claim 1 wherein the wall of the port and the location means or casing are provided so as to contact and define the shape of the opposing surfaces of the sleeve.

8. Apparatus according to claim 1 wherein a material used to form the sleeve is sufficiently deformable so as to take into account variance in the drive components.

9. Apparatus according to claim 1 wherein a material used to form the sleeve is substantially non-compressible so as to maintain the propeller and shaft in drive engagement.

10. Apparatus according to claim 1 wherein the sleeve is substantially non-conductive so as to electrically isolate the propeller from the said location means of the shaft.

11. Apparatus according to claim 1 wherein a deformable material is a polyurethane rubber.

12. A craft for water including a drive system as defined in claim 1.

13. Apparatus according to claim 1 wherein the said sleeve includes end portions and an intermediate portion located along the length of said sleeve.

14. Apparatus according to claim 13 wherein the thickness of walls of the said sleeve walls at said portions varies along the said length of the sleeve.

15. Apparatus according to claim 14 wherein the wall at the intermediate portion is thicker than the walls at said end portions.

16. Apparatus according to claim 1 wherein the sleeve is rotatable under the influence of the rotation of the said shaft located in said port.

17. A drive apparatus for a craft in water, said drive apparatus comprising a drive means, one or more shafts which are provided in connection with the drive means via one or more gear assemblies and at least one of said shafts having a free end with location means to allow the same to be located with a propeller of the said craft to impart rotational drive to the propeller and wherein said location means are at least partially located within a port in the body of the propeller and intermediate said location means and the walls of the said port there is provided an at least partially deformable sleeve which separates the propeller body from the said shaft and retains the propeller body with the location means, wherein a material is introduced in a liquid form into a cavity formed between the propeller body and the shaft location means, or casing when provided.

18. A method of forming a drive system for a craft in water, said method including the steps of providing a drive means, one or more shafts which are provided in connection with the drive means via one or more gear assemblies and at least one of said shafts having a free end, forming location means at said free end to allow the same to be located with a propeller of the said craft to impart rotational drive to the propeller when the shaft is driven to rotate by the drive means, positioning said location means at least partially within a port formed in the body of the propeller and, intermediate said location means and the walls of the said port there is provided a cavity and wherein a substantially non-conductive material is retained in said cavity so as to separate the propeller body from the said shaft whilst retaining the propeller body in contact with the location means, the said material being introduced into said cavity in a flowable form and then sets in position in said cavity.

19. A method according to claim 18 wherein when formed, a sleeve is substantially non-conductive and/or deformable and/or substantially non-compressible.

Description

(1) Specific examples of the invention are now described with reference to the accompanying drawings; wherein

(2) FIGS. 1a and 1b illustrate a drive system in accordance with one embodiment of the invention.

(3) FIGS. 2a and b illustrate a propeller in one form which can be used with a drive system in accordance with one embodiment of the invention;

(4) FIGS. 3a and b illustrate cross sections of the connection between the propeller and the drive shaft in accordance with one embodiment of the invention; and

(5) FIGS. 4a and b illustrate the method steps which can be followed in one embodiment for forming the connection between the drive shaft and propeller in accordance with FIG. 3.

(6) Referring firstly to FIGS. 1a and b, there is illustrated, schematically, one embodiment of a drive system for a craft, in this case a yacht 52. In this embodiment there is provided in the hull 54 an engine 56, connected by shaft 58 to gear box 60. This is in turn connected to shaft 62 which is connected to gear box 64 and, in turn, drive shaft 66. Connected to the free end 68 of the drive shaft 66 is a propeller 16 which has a body portion 70 with blades 72 depending outwardly from the body and which are driven by the rotation of the drive system.

(7) In FIGS. 2a and b there is illustrated a propeller 16 in accordance with one embodiment of the invention in which the blades 72a and 72b are movable between a storage position shown in bold lines in FIG. 2a and in FIG. 2b. The blades 72a, 72b move to an in use position about the pivot axis 24a and the in use position is shown in broken lines in FIG. 2a. The longitudinal axis 18 of the propeller is in line with the longitudinal axis 67 of the shaft 66.

(8) FIGS. 3a and b illustrate elevation and plan cross sectional views of the connection between the drive shaft 66 via location means 68 and the propeller body portion 70 in accordance with one embodiment of the invention. Only the body 70 of the propeller 16 is shown with the port 28 therein which has an open end 29 and into which there is provided and located the location means 68 of the shaft 66. In this case the location means includes splines 30 which run along the same and which engage, in this embodiment with splines 30 of a casing 32 which is located around the location means 68. This means that the casing 32, which is mechanically engaged with the location means 68, is effectively integrated with the same and rotates along with the location means 68.

(9) It should be noted that in alternative embodiment the casing 32 may not be provided. Furthermore, while the use of the spline drive connection formations as described in this embodiment of the invention is typical, it should be noted that this is not the only method of attaching the drive connection between the propeller to the drive shaft. Other engineering possibilities include options such as shrink fits, welding, tapered connections, with, or without, keyways and/or with nuts.

(10) In this embodiment, between the external surface 34 of the casing 32 and the internal surface 36 of the port of the propeller body portion 70 there is defined a cavity 38 which receives therein, a deformable non-compressible material to form a sleeve 40. It is shown that the sleeve 40 is annular in cross section along line AA. In this embodiment the thickness of the annular wall 41 varies along the length thereof. In the embodiment shown, the thickness varies such that the intermediate portion 42 of the wall, is thicker than the portions 44, 46 at opposing ends.

(11) While the material, which in one embodiment is polyurethane rubber, is deformable, the same is provided so as to be substantially not compressible at the pressures in which the drive system will be required to operate. This ensures that the movement of the propeller body portion 70 with respect to the drive shaft 66/casing 32 in the direction 48 is not possible and therefore the propeller is always maintained in the required location with respect to the drive shaft 66 so as to receive the rotating drive force therefrom as the shaft rotates and therefore allows the propeller to be driven to rotate in direction 50. In addition, the provision of the deformable material means that any relative movement which is caused by vibration, between the drive shaft 66 and the propeller body portion 70 is absorbed by a relative deformation of the material so that the deformation acts to dampen the effect of the vibration and hence allows the propeller blades to rotate in a more controlled and predictable path and therefore allows the propulsion which can be achieved by the drive system to be increased, be more efficient and be more reliable.

(12) A further feature is that the material used for the sleeve 40 is non-conductive and therefore acts to electrically isolate the drive shaft 66 from the propeller body portion 70 and therefore reduces the occurrence and speed of corrosion of both the propeller and the drive shaft 66.

(13) These advantages, alone and in combination, serve to extend the life of the propeller and the drive system as a whole.

(14) FIGS. 4a and b illustrate a particular series of method steps which can be performed to achieve the join between the propeller and the drive shaft in accordance with one embodiment of the invention.

(15) In FIG. 4a it is illustrated the manner in which the drive shaft 66 with the location means 68 at the free end, is located with the casing 32 thereon and the external face 34 of the casing is formed so as to provide the required shape of one side of the deformable material sleeve 40 which is to subsequently be engaged therewith. The location means 68 and casing 32 are then placed into the port 28 of the propeller body as shown in FIG. 4b and the internal face 36 of the propeller body port 28, is formed so as to form the opposing face of a mould 52 which has the varying wall thickness so as to provide the variation in the annular wall thickness of the sleeve 40 as defined previously.

(16) A liquid polyurethane rubber material is then poured into the mould cavity 52 to fill the same such that the sleeve wall 41 has varying thickness as discussed. It will therefore be seen that the thickness of the sleeve 40 wall 41 can be adjusted along its length by the suitable shaping of one or both of the surfaces 34, 36. The decision as to the thickness of the sleeve wall is made with respect to selecting whatever thickness best absorbs the torsional oscillations of any particular drive configuration with which the sleeve is to be provided and this may be achieved after testing various drive assemblies and then defining predetermined sleeve formation for each.

(17) In an alternative option to that shown in FIGS. 4a and b a solid preformed sleeve can be used and then the inner and outer components of the connection between the drive shaft location means 68 and the propeller body portion 70 are arranged to be placed around the same and in engagement therewith.

(18) Furthermore, in whichever embodiment, drive formations are typically provided on the respective surfaces 34, 36 of the propeller port and the drive shaft casing so as to allow the required rotational drive to be imparted from the casing to the propeller body via the deformable material sleeve 40 as the extent of deformation is not sufficient to prevent this from occurring whilst the deformability is sufficient to allow any vibration or clatter between the propeller body portion 70 and the drive shaft location means 68 to be dampened.