The invention relates to a hydrofoil.
Hydrofoils allow a board to lift out of the water during kite surfing or jet skiing in order to reduce the flow resistance. In the process, only a portion of the keel fin and the two wings remains submerged in the water.
Conventional hydrofoils have only limited adaptability to different purposes, and are bulky in their dimensions. In addition, the connecting area between the keel fin and the wings is subjected to strong stresses due to the forces which occur during operation.
The object of the invention is to improve a hydrofoil in consideration of the above-mentioned aspects.
This object is achieved by a hydrofoil comprising a keel fin having a first end portion for fastening to a board, and a front wing and a rear wing which are arranged one behind the other in the travel direction and are connected to a second end portion of the keel fin, wherein a connecting rod is situated on the second end portion of the keel fin and detachably connects the wings to the keel fin, and wherein a plate is situated on an outer side of the keel fin and on an outer side of at least one of the wings, and via detachable fastening means is braced to the connecting rod so as to detachably fasten at least one of the wings to the keel fin.
Since the front wing is generally located closer to the keel fin, the front wing is typically fastened to the keel fin in the manner described above. However, it is also possible to correspondingly affix the rear wing or both wings to the keel fin.
Whereas the connecting rod is able to absorb the bending moments, the plate is used primarily for transmitting the torsional moments between the wing in question and the keel fin.
The wings and the connecting rod may be easily replaced, if necessary.
Due to such a modular design, it is possible in particular to influence the handling characteristics of the hydrofoil for different purposes via the selection of the length of the connecting rod, and via the shape of the front and rear wings by using different front and rear wings.
In addition, each individual component may be optimized from a materials technology standpoint, as the result of which, among other things, the strength properties and stiffness properties in the connecting area between the keel fin and the wings may be improved.
Since the connecting rod may be designed to be very narrow, the resistance in the water may be further reduced.
Furthermore, the hydrofoil may be folded up very compactly, which is advantageous in particular for airline travel.
A large-surface introduction of force is made possible via the plate, and allows large tension forces in the connection. Wear and settling effects may be counteracted by simply tightening the fastening means. This is advantageous in particular when the keel fin and/or the wings is/are made of fiber composite material. The screw threads are situated in the steel elements, resulting in a precise, wear-resistant connection.
The plate may be situated in a recess which extends along the second end portion of the keel fin and one or both wings. The transmission of torsional moments is further improved in this way. For this purpose, the plate is preferably accommodated in the recess in a positive-fit manner.
In addition, the recess may be formed as a groove in the second end portion on the keel side, as the result of which the plate is easily accessible for mounting and dismounting the wings and optionally also the connecting rod. However, a lateral arrangement is likewise possible.
With regard to a favorable flow profile, the plate may be integrated into the outer contour of the hydrofoil. For this purpose, the plate may continue the outer contour of the second end portion of the keel fin and of the wing in question in a continuous manner, i.e. without interruption. A particularly compact design is achieved by a uniformly planar connection of the elements.
According to another embodiment, the plate is made of metal, thus enabling high tension forces when the wings and a keel fin are made of fiber composite material, since the plate broadens the supporting base of the clamping connection at the interface with the fiber composite material. However, the plate may be made of a material selected from metal, fiber composite material or a combination thereof.
As fastening means, threaded bolts may be provided which are inserted from the outer side of the plate and screwed to the connecting rod. This arrangement is particularly advantageous for replacing the wings and the connecting rod. The thread and the screw support in a connecting rod, as well as a plate made of steel or some other metallic material, allow a particularly precise, wear-resistant connection.
The plate may have an elongated design, and extends predominantly in the travel direction of a kiteboard equipped with the hydrofoil. The plate may extend parallel to the connecting rod.
The connecting rod may be detachably fastened to the second end portion of the keel fin in the manner explained above. In addition, a detachable fastening of a wing to the connecting rod, in particular a detachable fastening of the front wing to a front end of the connecting rod, may be achieved. Furthermore, the rear wing may also be detachably fastened to a rear end of the connecting rod.
The keel fin at its second end portion preferably forms a receptacle for the connecting rod, thus achieving a particularly stable force bracing and torque bracing. In particular, the keel fin at its second end portion may form a receptacle in the form of a passage opening through which the connecting rod is passed.
The keel fin and optionally also the wings are preferably made of a fiber composite material.
In contrast, with regard to a compact and stable design, the connecting rod is preferably made of metal, in particular steel and titanium alloys and aluminum alloys being suitable here. However, the connecting rod may also be made of a fiber composite material or a combination of the mentioned materials. Metallic threaded sleeves may optionally be embedded in the fiber composite material for bracing to the plate.
According to another embodiment, a connecting rod having a constant diameter is used, which is easily manufactured in different lengths. In particular, the length of the connecting rod may be varied in a range of 400 to 900 mm.
Suitable diameters for the connecting rod are in the range of 10 to 25 mm.
According to yet another embodiment, the invention provides a hydrofoil, comprising: a keel fin having a first end portion for fastening to a board; and a front wing and a rear wing which are arranged one behind the other in the travel direction and are connected to a second end portion of the keel fin; wherein a connecting rod is situated on the second end portion of the keel fin and detachably connects the wings to the keel fin; wherein a plate is situated on an outer side of the keel fin and on an outer side of at least one of the wings, and via detachable fastening means is braced to the connecting rod so as to detachably fasten at least one of the wings to the keel fin; wherein the keel fin at its second end portion forms a receptacle for the connecting rod; wherein the plate is arranged in a recess formed on the second end portion of the keel fin; and at least one bolt for jointly securing the plate and connecting rod at the second end portion of the keel fin.
According to yet another embodiment, the invention provides a board having a hydrofoil, said hydrofoil comprising: a keel fin having a first end portion for fastening to a board; and a front wing and a rear wing which are arranged one behind the other in the travel direction and are connected to a second end portion of the keel fin; wherein a connecting rod is situated on the second end portion of the keel fin and detachably connects the wings to the keel fin, and wherein a plate is situated on an outer side of the keel fin and on an outer side of at least one of the wings, and via detachable fastening means is braced to the connecting rod so as to detachably fasten at least one of the wings to the keel fin.
The invention is explained in greater detail below with reference to exemplary embodiments illustrated in the drawings, which show the following:
The exemplary embodiment in
The hydrofoil 1 comprises a keel fin 3, a connecting rod 4, a front wing 5, and a rear wing 6. These components are connected to one another via standardized interfaces, so that they may be individually replaced. This results in a modular system which allows a flexible adaptation to different purposes.
The keel fin 3 has a first end portion 7 for fastening to the board 2, and a second end portion 8 for joining the connecting rod 4. The keel fin preferably has a height of approximately 700 to 1000 mm, a thickness of approximately 10 to 30 mm, and a length of approximately 80 to 150 mm in the travel direction. The keel fin 3 is made, for example, of a fiber composite material such as carbon fiber-reinforced plastic (CFRP) or glass fiber-reinforced plastic (GFRP). However, it may also be made of an aluminum alloy or a laminated composite material.
The first end portion 7 may form a flange-like fastening portion 13 which forms a support surface 2 for the bottom side of the board which is larger than the remaining cross section of the keel fin 3.
The second end portion 8 of the keel fin 3 has a receptacle in the form of a passage opening 9 through which the connecting rod 4 may be passed. Instead of a passage opening 9, the receptacle may be designed as a recess that is open on one longitudinal side, in particular as a groove 12 in which the connecting rod 4 is fixed.
The front wing 5 and the rear wing 6 are fastened to the keel fin 3 via the connecting rod 4. During surfing, forces which occur at the wings 5 and 6 are supported against the keel fin 3 via the connecting rod 4 in the passage opening 9. The connecting rod 4 is prevented from rotating about its longitudinal axis A at the keel fin 3. This may be achieved, for example, by appropriate profiling of the connecting rod 4 and the passage opening 9, or with the aid of suitable fastening means.
In one shape of the connecting rod 4 having a circular cross section, the connecting rod 4 may be prevented from rotating by means of an additional longitudinal pin 14, for example, as illustrated in
In addition, the connecting rod 4 may be prevented from rotating by means of a bolt 17 or pin which extends into the end portion 8 and into the connecting rod 4, transversely with respect to the longitudinal axis A, as illustrated in
Another alternative is to use a connecting rod 4 having a square profile 18, as illustrated in
The connecting rod 4 is made of metal, preferably a steel or a titanium or aluminum alloy. The connecting rod has a diameter in the range of 10 to 25 mm, as the result of which the flow resistance in water remains low. The length of the connecting rod 4 is preferably in the range of 400 to 900 mm.
With regard to simple manufacture and installation, the connecting rod 4 may be designed with a constant diameter. However, it is also possible for only portions, such as the area which is guided in the passage opening 9 or groove 12, to be designed with a constant cross section.
The front wing 5 and the rear wing 6 are arranged one behind the other in the travel direction, and are detachably fastened to the respective ends of the connecting rod 4. In particular, the front wing 5 is situated at a front end 10, and the rear wing 6 is situated at a rear end 11, of the connecting rod 4, so that the front wing 5 is positioned in front of the keel fin 3 and the rear wing 6 is positioned behind the keel fin 3.
The fastening of the connecting rod 4 to the keel fin 3 as well as the fastening of the wings 5 and 6 to the connecting rod 4 in each case have a detachable design. As a result, connecting rods 4 of different lengths may be fastened to the keel fin 3 in order to change the position of the wings 5 and 6. In addition, different front and rear wings 5 and 6 may be fastened to the connecting rod 4.
The wings 5 and 6 may be made of fiber composite material, in particular carbon fiber-reinforced plastic (CFRP) or glass fiber-reinforced plastic (GFRP), or a laminated composite material.
For assembly of the hydrofoil 1, initially a connecting rod 4 having the desired length may be mounted on the keel fin 3 by inserting the connecting rod through the passage opening 9. The desired wings 5 and 6 are subsequently fastened to the connecting rod 4. If the receptacle on the keel fin 3 is designed as an open groove 12, it is also possible to initially attach the two wings 5 and 6 to the connecting rod 4, and then mount the entire unit on the keel fin 3.
The hydrofoil 1 may be disassembled very easily, for example to change the handling characteristics of the board 2 thus equipped, by exchanging the connecting rod 4 and/or the wings 5 and 6, and optionally also the keel fin 3.
Due to the modular design, a modular system is also made possible which easily allows a variety of boards 2 to be equipped with a foil 1.
Within the scope of a modular system, it is also possible to configure the connecting rod together with one of the wings as a unit. In this case, the wing in question and the connecting rod would then always have to be mounted and dismounted together. For this purpose, for example, the front wing together with the connecting rod may be produced as an integral component made of fiber composite material. Any required threads may be provided by embedding appropriate sleeves or the like made of metal.
The foil 1 may also be folded up very compactly for transport.
The hydrofoil 1 of the second exemplary embodiment has a connecting rod 4 which, the same as in the first exemplary embodiment, is situated on the second end portion 8 of the keel fin 3 and detachably connects the wings 5 and 6 to the keel fin 3.
The connecting rod 4 extends through a passage opening 9 provided in the keel fin 3, while the wings 5 and 6 are fastened to the ends 10 and 11, respectively, of the connecting rod. With regard to simple manufacture, the connecting rod 4 is designed with a circular cross section. However, other cross section profiles are also possible, as already explained above.
For fastening the front wing 5, a plate 20 is additionally provided which is situated on an outer side of the keel fin 3 and on an outer side of the front wing 5, and which thus partially overlaps both components 3, 5. The plate 20 is braced to the connecting rod 4 by detachable fastening means 21 in order to detachably fasten the front wing 5 to the keel fin 3. The end portion 8 of the keel fin 3 and the wing in question are positioned relative to one another via the plate 20, so that a longitudinal pin 14 according to
It is also possible to fasten the rear wing 6 to the keel fin 3 in a corresponding manner. In addition, both wings 5 and 6 may be detachably fastened to the keel fin 3 via a shared plate 20 or via their own plate 20. For this purpose, the particular plate 20 is braced against the connecting rod 4.
The bracing preferably takes place transversely with respect to the longitudinal direction of extension A of the connecting rod 4.
In the illustrated exemplary embodiment, the plate 20, which may have an elongated design in the travel direction and preferably runs parallel to the connecting rod 4, is mounted on the keel side. However, fastening on the side of the hydrofoil 1 is also possible.
For accommodating the plate 20, a recess 22 is provided on the keel fin 3, and may continue into the wing 5 in question. The recess 22 preferably extends along the second end portion 8 of the keel fin 3 and along at least one of the two wings 5 and 6.
In the illustrated exemplary embodiment, the plate 20 is accommodated in the recess 22 in such a way that the plate continues the outer contour of the second end portion 8 and of the wing 5 or 6 in question without interruption. In addition, the plate 20 may be accommodated in the recess 22 in a positive-fit manner.
The plate 20 as well as the connecting rod 4 are made of metal, whereas the keel fin 3 and the wings 5 and 6 are preferably made of a fiber composite material. As fastening means 21, threaded bolts may be used which are inserted from the outer side of the plate 20 and screwed to the connecting rod 4.
In the illustrated exemplary embodiment according to
In the fastening concept explained above, the connecting rod 4 is able to absorb the bending moments, while the plate 20 is used primarily for transmitting the torsional moments.
A large-surface, positive-fit introduction of force allows the keel fin 3 and the wings 5 and 6 to be made of a fiber composite material, while a metallic plate 20 in conjunction with the connecting rod 4 allows a stable, precise, and wear-resistant connection of the modular system. In addition, a compact, streamlined design is achieved by a uniformly planar connection of the elements.
Wear and settling effects in the fiber composite material may be easily eliminated by retightening the fastening means 21.
The invention has been explained in greater detail above with reference to exemplary embodiments. However, the invention is not limited thereto; rather, it encompasses all embodiments defined by the claims. In particular, individual technical features may also be combined with one another, even if this is not expressly described, provided that such a combination is technically possible.
Number | Date | Country | Kind |
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10 2014 101 536.3 | Feb 2014 | DE | national |
20 2014 103 591.5 | Aug 2014 | DE | national |
This application claims priority under 35 USC §119 to German Patent Application No. 10 2014 101 536.3, filed on Feb. 7, 2014, and German Utility Model Application No. 20 2014 103 591.5, filed on Aug. 1, 2014, the contents of each of which are incorporated herein by reference.