EP2242678A2 - Folding hull element - Google Patents

Abstract

The invention relates to a hull element (7), which is attached to the stern (1) or hull bottom (1b) by means of a hinge means (6, 6a) and enables active and passive trimming of the watercraft (1a), and at the same time also supports a watercraft lift (2) or watercraft steps (11) by means of the connection (8) or a connecting cylinder (18). The platform (3) or watercraft steps (11) can be activated by means of the acting cylinder (17b) and the connection (8) or connecting cylinder (18) on the hull element (7). If the watercraft lift (2) or the watercraft steps (11) are actuated by means of the acting cylinder (17a), the hull element (7) folds away such that the lift H of the watercraft lift (2) or the lift HT of the watercraft steps (11) is not impaired or limited.

Description

 Folding fuselage element

Technical area

The invention relates to a fuselage element which extends at the rear end of a watercraft and can be folded down as needed and at the same time serves as a flow and buoyancy body, as well as activating means for moving watercraft lifts, according to the preamble of the first claim.

State of the art

Movable attachments to the rear ends of watercraft with a flow claim trim tabs are known in this regard, which are manually, electrically or hydraulically moved, the mechanical spindle, and the electric and hydraulic cylinders are supported on the side wall at the rear (mirror) of a watercraft, as described in US Pat. No. 3,695,204

Watercraft lifts for swimmers or tenders are known to transport people or dinghies more comfortable and safe in or out of the water, as described in the patent DE 19963 057 C1.

Presentation of the invention

The invention is based on the object in a vessel equipped with a watercraft lift or watercraft stairs and a movable buoyancy body hull element to connect both so that on the one hand the hull of the vessel is extended, on the other hand, the buoyancy body hull element supports the watercraft lift or the watercraft stairs with its buoyancy. In addition, the trim of the vessel when loaded in the rear area is also improved by the additional static or dynamic buoyancy without affecting the path for lowering the watercraft lift or the watercraft stairway by folding the buoyant body body member away.

Watercraft lifts are becoming more and more popular, as they allow dinghies and jet skis to be taken in elegantly and efficiently, or they can be launched simply and easily. In addition, such lifts or a corresponding lowerable stairs are also used for people like, especially in larger yachts, where the way from board to or from the water corresponding distances means. The photographs of dinghies overhanging the stern of the vessel are a burden on the watercraft mirror and also leads to a whitewash of the entire vessel, as well as the parking position of a weighty dinghy outside the rear of an extremely unfavorable weight distribution for the entire vessel, especially during acceleration to the sliding phase and at the same time a permanent load on the tail structure, especially in waves due to the fluctuating dynamic forces, which triggers such a dinghy and the lift itself at this exposed point.

The invention solves several points of conflict in that the watercraft lift under the platform has a corresponding rotatably mounted buoyancy body hull element attached to the stern of the watercraft which extends downstream and is thus advantageously below the platform, wherein the platform and the buoyant body hull element are interconnected by means of a connection means , Thus, the load on the transom is reduced by the buoyancy of the buoyant body hull element or canceled completely. This additionally ensures that not the entire weight of the lift the Liftbefestigungsträgern the rear part loads, but a part of the load on the attachment to the trunk end, respectively. rotatably mounted on the lower rear part of the vessel buoyancy body hull element, this is additionally supported there. In particular, in swell or wave jumping forces occur at the rear of the vessel, which in addition by means of the buoyancy body hull element in the lower part of the rear, respectively. Fuselage are introduced and thus leads to a distribution of the forces acting. If the lift can not be raised due to a technical defect, this is done elegantly by means of the lift force previously set by the shipyard on the buoyant body hull element, which is advantageously higher than the weight of the lift or stairs, so that the lift platform or stairs lift over the waterline, until it can be locked up.

Due to the static and dynamic buoyancy of the buoyant body hull element, the watercraft with the stern does not hang so deep in the water, which otherwise leads to an unsightly trim position of the watercraft. By substitution of the connecting means by an active cylinder, the trim of the watercraft itself can be adjusted at any time and precisely with the buoyant body hull element when driving. Correct trimming is not only a visual concern, but also significantly improves the speed of the vessel, reduces fuel consumption and makes the hull of the vessel softer into the waves. All these technical and hydrodynamic advantages due to the buoyant body hull element in no way limit the stroke of the watercraft lift or the watercraft stairs, as this is folded away when needed.

According to the invention, this is achieved by the features of the first claim.

The essence of the invention is to support a buoyancy body hull rotatably mounted at the stern of a craft and mechanically connected to a watercraft lift or watercraft stairway to support the watercraft lift or watercraft staircase at the tail end by static and dynamic buoyancy, thereby enhancing the trim of the craft thereby restricting the stroke of the watercraft lift or watercraft stairs by the buoyancy body fuselage element is folded away when needed.

Further advantageous embodiments of the invention will become apparent from the dependent claims. Brief description of the drawings

In the following, embodiments of the invention will be explained in more detail with reference to the drawings. Identical elements are provided with the same reference numbers in the various figures.

Show it:

Fig. 1 is a schematic side view of a stern of a vessel with a watercraft lift attached thereto, a rotatably mounted body element, and a

Connecting means between lift and fuselage element

Fig. 2 is a schematic side view of a stern of a vessel with an attached watercraft staircase, a rotatably mounted body member, and a connecting means between the lift and fuselage element

2a shows a schematic side view of an unlocked with

Time delay mechanism for a lockable gas spring

3 shows a schematic side view of a stern of a vessel with a watercraft lift fastened thereto and a rotatably mounted torso element engaging under the watercraft body and a connecting means between the lift and the body element

4a is a schematic side view of a stern of a vessel with an attached watercraft lift and a rotatably mounted fuselage element, and a connecting means between the lift and fuselage element and a working cylinder which acts on one of the pivot arms and is supported on the stern of the vessel

Fig. 4b is a schematic side view of a stern of a vessel with a watercraft lift attached thereto and a rotatably mounted fuselage element, and a connecting means between the lift and fuselage element and a working cylinder which acts on the fuselage element and is supported on the stern of the vessel 5 shows a schematic side view of a stern of a vessel with an attached watercraft lift and a rotatably mounted fuselage element, as well as an adjustable connecting means between the lift and fuselage element

6 shows a schematic side view of a stern of a vessel with an attached watercraft lift and a rotatably mounted fuselage element, and a connecting means between the lift and the fuselage element and two lifting stops

7 shows a schematic rear view of a stern of a vessel with a watercraft lift fastened thereto with its pivoting device and a rotatably mounted fuselage element which is connected to the watercraft lift by means of a laterally deflectable connecting means

8 is a schematic top plan view of a watercraft stern with a rotatably mounted fuselage element attached thereto and a hinge angle element

Fig. 9 a) is a schematic side view of a rotatably mounted fuselage element with a bottom step, which b) at right angles or obliquely or forms a free-shaped recess

Fig. 10 is a schematic rear view of a rotatably mounted fuselage element which has an entangled floor

Fig. 11 is a schematic side view of a rotatably mounted fuselage element with a floodable chamber and a lateral stabilizing sheet

12 shows a schematic side view of a rotatably mounted fuselage element with an integrated transverse radiator, separate trim flap, underwater lamp and engine exhaust gas passage, as well as connecting lines to the watercraft.

Only the elements essential for the immediate understanding of the invention are shown schematically. Way to carry out the invention

1 shows a schematic side view of a stern 1 of a watercraft 1a with a watercraft lift 2 mounted thereon, consisting of a platform 3 on which a swivel arm set 4, consisting of the swivel arms 4a, 4b and in the form of a parallelogram, is attached to a console 5 is mounted rotatably mounted and the console 5 is fastened to the rear 1. Details such as bearings and the like are hidden as well as the active cylinder for the raising and lowering of the platform 3. The fuselage bottom 1b with the uprising is only hinted at here and the Aufkimmung the fuselage element 7 is hidden.

At the rear 1, the rotatably mounted, by means of a hinge means 6, hull element 7 is attached. The watercraft lift 2 and the fuselage element 7 are connected with a connecting means 8 rotatably connected to each other by means of the storage 8a.

The rotatably mounted fuselage element 7 has a buoyancy body with a static buoyancy as long as the watercraft 1 a rests in the water and has a dynamic buoyancy when the watercraft 1 a drives, resp. up to a certain driving speed. The hull element 7 can also be mounted in a version without buoyancy, so that it initially acts similar to a very large trim flap, i. produces no buoyancy at rest, but provides a dynamic buoyancy when driving and new, again generates no buoyancy at high speeds, the latter, for example, is achieved by means of a gradation 9 in the fuselage element 7. By pivoting the Schwenkarmsatzes 4 moves the platform 3 upon actuation of a force downwards as indicated by arrow H. To provide enough space for the

To secure the fuselage element 7 or other technical means at the tail 1 drives the platform on rails 10 according to arrow L, which positively controlled, for example by means of a push rod which is mounted between console 5 and platform 3, or the platform 3 shifts horizontally by activating a hydraulic - or electric cylinder. On the platform, the connecting means 8 is attached, which is connected to the fuselage element 7 and when lowering the platform 3, the fuselage element 7 weg- resp. works down and thus elegantly releases the stroke H for the platform 3. Fig. 2 shows a schematic side view of a stern 1 with an attached watercraft staircase 11 which serves as a platform 3 in the horizontal and can be pivoted downwards at the joint 12 and thus serves as a staircase by the footsteps are rotated horizontally and always in the horizontal position remain, which advantageously requires two joints 12 at the rear 1.

Otherwise, 3 recesses are mounted in the platform, which form fixed stairs 13. So that the stairs 13 are not exposed in the horizontal, they can be made accessible by a suitable cover 15. By means of a Abdeckschamiers 14, the accessible cover 15 according to arrow T manually or by means of active cylinder or specific gas spring

14a, also blockable, by means of the unlock key 14b and 14c unlock line, be unfolded. The cover 15 may e.g. have internal stairs 16 and when fully extended to position A, allow even more comfortable access to the water. Half unfolded, e.g. in position B, and locked with means such as e.g. by means of a blockable, i. unlockable gas spring 14a, and without or only partially formed with the inner stairs 16, the rest of it equipped with a flat, non-slip coating, the inside of the cover 15 forms an additional platform under water. The covering hinge 14 can also be attached laterally to the watercraft staircase 11 and thus the cover 15 can be folded laterally, so that the inner stairs 16 together with the stairway 13 forms an even wider but less long staircase, which likewise locks in place, in particular against waves can be.

Under the watercraft staircase 11 is the body member 7, fixed by means of a hinge means 6 at the rear 1, which is forcibly folded by the connecting means 8 in the lowering of the watercraft stairs 11 in lockstep and this is the stroke HT of the watercraft staircase 11 thus not in the way. If the fuselage element 7 at the same time a static buoyancy means, this stabilizes the vessel 1a before too strong

Heeling when entering the watercraft staircase 11, this should not be placed in the middle of the tail 1.

Not shown is a cord, which allows the retrieval of the cover 15, to which a hinged rod is attached and thus additionally as a railing Help can be used.

If the watercraft staircase 11 is not mounted over the entire area of the watercraft 1a, but only in a partial area, then an effective cylinder 7, which can raise and lower the watercraft staircase 11, can be fixed directly between the watercraft staircase 11 and the rear, according to the arrow HT.

2a shows a schematic side view of an unlock key 14b, which has a time delay mechanism 35 for a lockable gas spring 14a, which can be unlocked when needed and automatically locked again after a desired time. The unlocking of a lockable gas spring

14a normally takes place via a pusher 36 and the unlocking line 14c, which here triggers a valve, not shown, in the releasable gas pressure spring 14a. The time delay mechanism 35, which is attached to the unlock key 14b housing, not shown, and engages the transmission lever 41, includes a liquid-filled, e.g. Oil or silicone or similar

Liquid, a rotatably mounted brake cylinder 37 with a piston 38 and with a pressure spring 39 placed therein is now pulled on the lever button 40 according to arrow R, the pusher 36 is activated via the transmission lever 41 and hinge pin 42. When releasing the lever button 40, this will not immediately fall back to its original position on the compression spring 39, but is slowly returned, braked by the piston 39 which has a recess or a hole pattern, so that the liquid trapped therein only slowly from one piston chamber into the other can flow. Thus, the pusher 36 is pressed over a certain time axis, whereby the releasable gas pressure spring 14a remains unlocked over this time.

3 shows a schematic side view of a stern 1 with a watercraft lift 2 attached thereto and a rotatably mounted fuselage element 7 engaging under the watercraft fuselage 1b. The pivotal mounting by means of the upstream hinge means 6a is used in the case of the platform 3 is a very large

Stroke H moves or and the fuselage element 7 is designed such that it would come between hull element 7 and the lowering of the platform 3 to collision. By the displacement of the hinge means 6 from the rear 1 further forward in the direction of travel of the watercraft 1a under the watercraft body 1b, is made room by the modified kinematics, so that by means of the connecting means 8 between the platform 3 and fuselage element 7, the latter so folds down that the entire stroke H of the platform 3 is ensured. The folding up of the fuselage element 7 is limited by this Drehbefestigungsart.

4a shows a schematic side view of a stern 1 with an attached watercraft lift 2 and a rotatably mounted fuselage element 7, and a connecting means 8 between platform 3 and fuselage element 7, and an active cylinder 17a which acts on the pivot arm 4b and is thereby supported on the rear 1. The active cylinder 17a thus also acts on the hull element 7 via the connecting means 8. The active cylinder 17a can be operated hydraulically, pneumatically or electrically. A special position is the application of a gas spring 14a, in particular a lockable, which is activated by the unlock key 14b and the weight of a person needs to the watercraft lift 2 or the watercraft stairs 11 to move down. Conversely, no person on the watercraft lift 2, resp. Watercraft stairs 11 are to raise them again, this is done solely by the retraction of the piston of the gas-filled cylinder of the gas spring 14a. Instead of having attached as usual a movable platform without solid ground on the tail 1, a buoyancy force F1 is generated by means of the fuselage element 7, which acts against the weight F2 of the watercraft lift 2 and thus positively supports the trim of the watercraft 1a. In addition, e.g. the hydraulic system do not want to work and in the process the platform has previously been driven downwards, then, by means of the buoyancy of the fuselage element 7, transmitted by the connecting means 8, the

Platform 3 are pushed up until it automatically locks and locks at its destination, for which function the active cylinder 17a, b must be switched first without pressure. If the platform 3 occupied by a tender, so is a high load on the console 5, resp. to observe at the rear 1, wherein by means of the body member 7, the load on the console 5 can be optimally reduced.

Even with a permanently mounted platform 3 directly on the vessel 1a, the tail 1 is relieved by means of the buoyant body element 7 and can thus also be used only as a pure dynamic trim element or and a passive trim function in the rest position of the vessel 1a über-. take, especially if in this big engines are housed in the rear area.

4b shows a schematic side view of a stern 1 with a watercraft lift 2 attached thereto and a rotatably mounted fuselage element 7, as well as a

Connecting means 8 between platform 3 and fuselage element 7, and an active cylinder 17b or gas pressure spring 14a, which engages the body member 7 and is supported on the rear 1. When the action cylinder 17b extends, the body member 7 is pushed down and, by means of the connection means 8 between the body member 7 and platform 3, the latter is pulled down and has the same function as a conventional watercraft lift 2 with its stroke H. This configuration is of course also applicable to the watercraft staircase 11.

5 shows a schematic side view of a stern 1 with an attached watercraft lift 2 and a rotatably mounted fuselage element 7, and a connecting means 8 between platform 3 and fuselage element 7, and a connecting cylinder 18 which is installed instead of the connecting means 8. The function of the rotatably mounted connection between platform 3 and fuselage element 7 remains, except that in this configuration, in which the active cylinder 17a engages the pivot arm 4b and thus the watercraft lift 2 is firmly clamped, the connection cylinder 18 can be moved in and out separately and allows the body member 7 to exercise its own trim tab function. This covers all the advantages of a standard trim flap. If the watercraft lift 2 are driven down, is by means of

Position detection and control via an electronic means 19 and a sensor 20, the connecting cylinder 18 back to its predetermined starting position, e.g. moved half way or between fully or half extended position, detected by the sensor 20a. Then the watercraft lift 2 can only come into action. Also, by means of the electronic means

19, the hull element 7 at high speed, detected by the speed sensor 21, such as GPS or dynamic pressure or engine speed and the like, completely on, that are powered up, so that at the bottom of the fuselage element 7, the water flow no Coanda effect can be generated and thus the Water flow is completely detached and the harmful frictional forces do not continue to occur.

6 shows a schematic side view of a stern 1 with an attached watercraft lift 2 and a rotatably mounted fuselage element 7, as well as a

This relieves the connecting means 8 or the connecting cylinder 18 in pressure surges which otherwise act permanently in the swell of the body member 7 on the connecting element 8 and ultimately on the platform. 3 In order to avoid these pressure surges, instead of the stroke stop 22a or in addition thereto, the stroke stop 22b can be mounted between the body element 7 and the rear 1. The stroke stop 22b may be designed to be fixed or variable, so that it does not restrict the connecting cylinder 18, this should raise the body member 7 so that it completely frees itself from the damaging from a certain speed flow resistance. The strongest forces occurring in the swell are thus, apart from the hull element 7, received by the stroke stop 22b and rear 1, the connecting means 8, respectively. the connecting cylinder 18 are thus only a spacer between the platform 3 and the fuselage element 7.

Fig. 7 shows a schematic rear view of a stern 1 with a watercraft lift 2 attached thereto and a rotatably mounted fuselage element 7 by means of the hinge means 6, and a connecting means 8 which has a deflection bearing 23 at both ends, e.g. By means of a cardan joint or ball joint, so that when folding the inclined body member 7 relative to the horizontal platform 3, this leads to a geometric offset x, but the Auslenklagerung 23 takes this fact into account and thus the resulting lateral deflection of the connecting means 8 tracks. If no deflection bearing 23 is desired on the platform 3, then the offset x on the body element 7 can be compensated for by means of a side slide or the like, which is not shown here.

FIG. 8 shows a schematic top view of a tail 1 with a hinge angle element 24 fastened thereto with the inclined hinge means 6 at an angle z, FIG. on which the body element 7 is mounted. The angle z should correspond approximately to the acceleration of the fuselage bottom 1b, which leads to a considerable reduction of the offset x on the fuselage element 7. Of course, the hinge angle element 24 may be an integrated molded part in the vessel 1a and would then be omitted as a separate part.

Fig. 9 shows a) a schematic side view of a rotatably mounted fuselage element 7 with a gradation 9, so that at low to medium speed, the bottom 25a, b of the fuselage element 7 is flowed through by the water and thus generates a dynamic buoyancy. At higher speed, the flow travels at the step 9, the bottom 25a continues to provide buoyancy and thus supports via the connecting means 8 or stroke stop 22a the platform 3, while the bottom 25 b is no longer flowed and thus generates no frictional resistance. By raising the hull element 7 at the stern 1, the bottom 25 a of the. From a predetermined speed

Flow are released by the flow already tears off at the tail 1. Fig. 9b shows the various configurations of the bottom 25a, b. Depending on the type of vessel and the task, the grading may be oriented at right angles 9a to the flow, or at an oblique angle 9b, or in a non-straight shape 9c.

Fig. 10 shows a schematic rear view of a rotatably mounted hull element 7, which has an entangled underside 25c, i. The intake in the front part of the fuselage element 7 is approximately identical to the upturn of the fuselage bottom 1b of the watercraft 1a, with the intake on the outflow side being increasingly reduced. Particularly in the case of a heavy watercraft 1a, in the transitional phase from the displacement phase to the gliding phase, the flatest possible trim flap would be advantageous, i. with as little lift-up as possible in order to generate as much buoyancy in the rear area as possible. This is achieved by means of the entanglement of the bottom 25 c of the fuselage element 7 in an ideal manner.

The entanglement can also be achieved in multiple horizontal or slightly inclined longitudinal stages and does not necessarily have to be fluid. 11 shows a schematic side view of a fuselage element 7 with a floodable chamber 26, which can be pumped into or out of the fuselage element 7 by means of a pump 27 and the pipe 28. The flooding of the fuselage element 7 leads to a stabilization of the watercraft 1a lying in front of it, since it makes it altogether more difficult and thus the whole

Hull of the watercraft 1a lowers and this circumstance in turn leads to a further stabilization of the vehicle. Another means for stabilizing a vehicle can be effected by means of a lateral stabilizing plate 29 which acts like a slosh plate and dampens the rolling of the watercraft 1a, as soon as the fuselage element 7 is folded down and the stabilizing plate 29 is located under the waterline WL over a large area.

12 shows a schematic side view of a rotatably mounted fuselage element 7 with an integrated transverse radiator 30. Due to the fixed connection between the fuselage element 7 and tail 1 by means of the hinge means 6, a push mark can also be provided

Transverse radiator 30 are used, such. a standard transverse radiator or a jet propulsion with a suitably directed jet jet, without thereby exposing the swivel arm set 4 to a lateral force. Furthermore, a separate trim flap 31 can be integrated into the fuselage element 7, in the case no connecting cylinder 18 is provided. In addition, is the buoyant

Fuselage element 7 enough space to install a lighting fixture 43 therein, instead of cutting a hole in the hull of the vessel 1a and to constantly have to take care of the tightness of the element. By far, the exhaust gases of the engines are always an issue and the farther away from the rear 1 these are omitted, the more pleasant it is for the

Passengers aboard a watercraft 1a, which is best achieved with the engine exhaust passage 32 through the hull element 7. Due to the hinged fuselage element 7, the exhaust hose 33 is divided into two or telescopic or designed as a bellows or the like. The hydraulic or electrical leads 34 have a corresponding shape of wave to the

Distance offset when folding to compensate.

Of course, the invention is not limited to the embodiments shown and described. LIST OF REFERENCE NUMBERS

1 tail

1a watercraft

1b hull bottom

2 Waterfall I ift

3 platform

4 swivel arm set

4a, 4b pivot arms

5 console

6,6a hinge means

7 fuselage element

connecting means

8a storage

9, a, b, c grading

10 rail

11 watercraft stairs

12 joint

13 stairs

14 cover hinge

14a gas spring

14b unlock key

14c unlock line

15 cover

16 internal stairs

17 a, b active cylinder

18 connecting cylinders

19 electronic means

20 sensor

21 speed sensor

22a, b Stroke stop

23 Auslenlagagerung

24 hinge angle element 25a, b, c bottom

26 floodable chamber

27 pump

28 pipe

29 stabilizing sheet

30 transverse radiators

31 trim flap

32 engine exhaust passage

33 exhaust hose

34 supply line

35 time delay mechanism

36 pushers

37 brake cylinder

38 pistons

39 compression spring

40 lever push button

41 transmission lever

42 hinge pins

43 Lighting fixtures

H lift path platform

HT stroke staircase

T pop-up cover

R lever push-button release path

G exhaust path

F1 buoyancy

F2 weight

WL waterline

Claims

claims

1. hull element (7) on a watercraft (1 a), characterized in that this at the rear (1) or on the hull bottom (1b) by means of a

Hinged means (6,6a) is mounted rotatably mounted and with the watercraft lift (2) or watercraft stairs (11) by means of a connecting means (8) or connecting cylinder (18) is connected.

Second hull element (7) according to claim 1, characterized in that the connecting means (8) or connecting cylinder (18) has a bearing (8a) or and a Auslenklagerung (23).

3. fuselage element (7) according to claim 1, characterized in that the watercraft lift (2) comprises a Schwenkarmsatz (4), a platform (3) and a bracket (5) which is mounted on the rear (1) comprises.

4. fuselage element (7) according to claim 3, characterized in that the watercraft lift (2) rails (10), activated by means of a positive control or by means of hydraulic or electrical.

5. fuselage element (7) according to claim 1, characterized in that the watercraft staircase (11) comprises a platform (3) with stairs (13) and at least one joint (12) which is mounted on the rear (1) comprises.

6. fuselage element (7) according to claim 1, characterized in that the watercraft lift (2) and the watercraft staircase (11) by means of an active cylinder (17a) or a gas spring (14a) are activated directly, by this on the pivot lever (4a or 4b) attack and thus the activation of the stroke H or HT of the platform (3) or watercraft staircase (11).

7. fuselage element (7) according to claim 1, characterized in that the WasserfahrΣeuglift (2) and the watercraft stairs (11) by means of an active cylinder (17b) or a gas spring (14a) are indirectly activated by these attack on the body element (7) and by means of the connecting means (8) or connecting cylinder (18), the activation of the stroke H or HT of the platform (3) or watercraft staircase (11) takes place.

8. fuselage element (7) according to claim 6 and 7, characterized in that the active cylinder (17 a, 17 b) acts electrically or pneumatically or hydraulically.

9. fuselage element (7) according to claim 1, characterized in that the lowering of the watercraft lift (2) or watercraft stairs (11) has a folding of the fuselage element (7) has the consequence.

10. fuselage element (7) according to claim 1, characterized in that the active cylinder (17 a) a sensor (20) is mounted, which is connected to the electronic means (19), with the command circuit which causes the active cylinder (17 a) can only be activated when the connecting cylinder (18) is in a predetermined starting position, detected by means of the sensor (20a).

11. fuselage element (7) according to claim 1, characterized in that the connecting cylinder (18) from a speed, detected by means of the speed sensor (21), retracts and thus the hull element (7) starts up.

12. fuselage element (7) according to claim 1, characterized in that between the watercraft lift (2) or the watercraft lift (11) and the fuselage element (7) a stroke stop (22 a) or and between the rear (1) and the fuselage element (7 ) is a rigid or variable stroke stop

(22b) is located.

13. fuselage element (7) according to claim 1, characterized in that at the rear (1) by means of a hinge angle element (24) an inclined hinge means (6) at an angle (z) to the rear (1) is mounted and on the hinge means (6) the body element (7) is mounted. i

14. fuselage element (7) according to claim 1, characterized in that the hull bottom (1b) by means of a hinge angle element (24) an inclined hinge means (6a) at an angle (z) to the rear (1) is mounted on the hinge means (6a) Fuselage element (7) is mounted.

15. fuselage element (7) according to claim 1, characterized in that the gradation (9) at a right angle (9 a) or at an oblique angle (9 b) or in any shape (9 c) to the direction of travel of the watercraft (1 a) on the Bottom (25a, 25b) of the fuselage element (7) is mounted.

16 fuselage element (7) according to claim 1, characterized in that up to a certain speed of the watercraft (1 a), the lower sides (25 a) and (25 b) are flown and from an overlying

Speed only the bottom (25 a) or no bottom (25 a, 25 b) is flown.

17. fuselage element (7) according to claim 1, characterized in that this generates a static or dynamic buoyancy force F1 and directly or indirectly against the weight force F2 of the watercraft lift 2 or watercraft staircase 11 or the stern (1) acts.

18 fuselage element (7) according to claim 17, characterized in that the body member (7), which generates a static buoyancy force F1 and an effective cylinder (17b), with removed connection (8) or

Connecting cylinder (18), is used as an active trim element and in the rest position of the watercraft (1 a) serves as a passive trim element.

19. fuselage element (7) according to claim 17, characterized in that the fuselage element (7) generates a dynamic buoyancy force F1, which the platform (3) or the watercraft staircase (11), with pressure release of the active cylinder (17a, 17b), this over the Waterline (WL) lifts.

20. fuselage element (7) according to claim 1, characterized in that the underside (25 a) is entangled and the Aufkimmung the fuselage element (7) downstream is almost or completely flat.

21 fuselage element (7) according to claim 1, characterized in that in the fuselage element (7) is a floodable chamber (26) which can be flooded by means of a pump (27) or quasi pumped empty or and on the fuselage element (7) a stabilizing plate ( 29) is attached.

22 fuselage element (7) according to claim 1, characterized in that a transverse radiator (30) or a separate trim flap (31) or and an exhaust gas passage (32) and / or a lighting body (43) is located in the body element (7).

23. fuselage element (7) according to claim 1, characterized in that the associated watercraft lift (11) has a cover (15) which has an internal steps (16) or and a flat surface and can be opened by means of a covering hinge (14) ,

24. fuselage element (7) according to claim 23, characterized in that the cover (15) has a watercraft lift (11) fixed gas spring (14 a), which one by means of a

Time delay mechanism (35) equipped unlock key (14b) is connected.

25 fuselage element (7) according to claim 23, characterized in that the cover (15) can be locked with means in any position.

26. fuselage element (7) according to claim 23, characterized in that between the watercraft lift (11) and the cover (15) there is a cord and thereon a fold-out rod.