EP1516812A1 - Hull appendix for a watercraft - Google Patents

Abstract

The hull appendage (2), in particular, in the form of a keel or a rudder for a vessel comprises a body (4) incorporating an elastic material at least on parts of its outer surface (6).

Description

The invention relates to a fuselage, in particular keel or Oars, for a watercraft, with a body of one Outside surface is limited.

Especially if the hull appendage is a keel or a Oars, the body usually takes the form of a defined one Profils formed from its outer surface. The same is true for example, for moving fins. Such hull appendages can be used on surface vehicles as well Be mounted underwater vehicles.

There are now applications in which watercraft shock waves can be exposed. This is the case, for example, if Geodetic measurements are made where targeted Explosions are triggered. Also in military operations there is a risk of shock wave effects, the For example, be triggered by mines or depth charges. In In these cases, the hull appendages are particularly vulnerable, since they are for a high surface in relation to their volume and to others have a relatively weak construction.

It is therefore an object of the invention for a hull appendage in the To propose essentially shock resistant construction.

This object is achieved in that the body at least partially has elastic material on its outer surface.

In this case, the invention makes use of the knowledge that elastic material pressure influences from the outside against yielding is, but otherwise remains dimensionally stable. Because it tends to be in regularly to return to its original shape after the outer one Pressure influences have subsided. To unwanted deformations already during normal hydrodynamic operation should avoid using the elastic material used with such Hardness can be chosen so that it gives way only under high pressures by shock waves, but not in normal operation. By the use of such elastic material can be on easy way to absorb shock waves well and thus in the Realize shockproof hull appendages.

Preferably, the outer surface should be substantially complete having elastic material.

Conveniently, the elastic material should be at least one Layer be provided on the outer surface.

Furthermore, the outer surface itself may be at least partially elastic Be formed material and / or the outer wall at least partially having elastic material.

In a further preferred embodiment, the body is made at least partially, preferably completely, of elastic material.

The body may be provided with at least one reinforcing element be. Such a reinforcing element, of which usually a Plural are provided, can fulfill several tasks in Depending on the application either alternatively or at least partly come to fruition together: First, such a Reinforcement element for stiffening and thus for increasing the statics serve the body, and on the other hand, such Reinforcing element in the manufacture of the fuselage as Mounting aid used to build the body. After all Such a reinforcing element can also be anchored a shaft o. The like. As a rudder stock be provided.

Another particularly preferred embodiment is characterized that the body contains at least one gas, preferably air, filled, air-tight and waterproof closed cavity contains. With the Training such a cavity can be constructive particularly simple and thus skillful way an increase in Shock absorption effect with simultaneous significant reduction achieve the total weight, since the gas-filled cavity a Type pad for absorption of external shock waves forms.

Usually in the body several cavities behind, under and / or arranged side by side and by wall sections from each other separated, which at the same time also the before-mentioned Can form reinforcing elements.

Preferably, the body has at least one wall section elastic material on the one side inside delimited at least a portion of a cavity and at its the other side forms at least a portion of the outer surface, wherein alternatively, an internal part of a reinforcing element and thus can not be elastic.

If at least one reinforcing element of the previously described Art is provided, this should be on at least one wall section attached and preferably disposed within this.

The elastic material should have a hardness of about 70 to 100 Shore A, preferably 80 to 95 Shore A, as well as an elongation at break greater than 250%.

Finally, as a suitable elastic material, e.g. polyurethane shown, which can be used as a solid material, wherein of course, the use of other materials with comparable properties is conceivable.

Figur 1

im Querschnitt eine erste Ausführung eines Ruderblattes mit der erfindungsgemäßen Konstruktion;

Figur 2

das Ruderblatt von Figur 1 im Längsschnitt; und

Figur 3

im Querschnitt eine zweite Ausführung eines Ruderblattes mit der erfindungsgemäßen Konstruktion.

Hereinafter, preferred embodiments of the invention will be explained in more detail with reference to the accompanying drawings. Show it:

FIG. 1

in cross-section, a first embodiment of a rudder blade with the construction according to the invention;

FIG. 2

the rudder blade of Figure 1 in longitudinal section; and

FIG. 3

in cross-section, a second embodiment of a rudder blade with the construction according to the invention.

In Figures 1 and 2 is an example in transverse and longitudinal section Ruderblatt 2 shown that a body 4 and a body. 4 has limiting, profiled outer surface 6.

The body 4 is made of elastic solid material, preferably a hardness of about 80 to 95 Shore A and an elongation at break greater than 250% and has polyurethane. Such elastic Material can absorb shock waves well, since it influences pressure is compliant outside, but otherwise remains dimensionally stable. Because it regularly tends to return to its original form after the external pressure influences have subsided. Around In contrast, unwanted deformations already during the to avoid normal hydrodynamic operation, lies the Shore hardness at least in the specified range, so that the elastic material only gives way under high pressures, which impinge upon impact from external shock waves, but not during normal operation. Since the material described thus sufficient shock resistance offers from the outside impinging pressure waves, is in the Essentially shock-resistant body 4 created.

As FIGS. 1 and 2 also show, are within the Body 4 a plurality of successive cavities 8 formed, each closed and containing air. Usually are over the vertical height of the rudder blade 2 several such accordingly superposed arrangements of consecutive Cavities 8 provided. Each of the cavities 8 is in air and closed watertight and contains air. Thus, each cavity 8 a kind of cushion for better absorption of external shock waves.

The formation of the cavities 8 creates a circumferential Outside wall 10, which limits the cavities 8 inwards and at their Outside the profiled outer surface 6 forms, and the cavities. 8 each separating partitions 12th Thus, in the illustrated embodiment, the body 4 substantially from the circumferential outer wall 10 and the partitions 12th

As can be seen from FIGS. 1 and 2, a body 4 is inserted into the body 4 Inserted skeleton, which consists of several reinforcing elements 14 composed. The reinforcing elements 14 are plate-shaped formed, preferably made of sheet steel, light metal or Plastic and extend within the outer wall 10 and the Partitions 12 each in the longitudinal direction. That of the Reinforcement elements 14 formed skeleton can do several tasks meet, either individually or at least partially come to fruition together: First, the skeleton is used for Stiffening of the body 4 and thus to obtain a certain Dimensional stability. On the other hand, the skeleton in the production of the Body 4 serve as an assembly aid, in particular in connection with the formation of the air and watertight cavities 8 and the profiled outer surface 6. Namely when as elastic material a Plastic composition of the type specified above is used, the is flowable, the body 4 is usually made by casting, wherein the framework consisting of the reinforcing elements 14 previously arranged in the appropriate form and during the Casting serves as a kind of proppant.

Finally, the skeleton can also anchor an in FIG 2 rudder stock 15 shown in sections may be provided.

If several arrangements of successive cavities 8 are provided over the vertical height of the rudder blade 2 should also accordingly several arrangements of Reinforcement elements 14 in the manner previously described in provided different heights within the rudder blade 2 which gives a truss-like skeleton over the vertical Height results. These arrangements of Reinforcement elements 14 be interconnected by that at least one of the reinforcing elements 14 over the entire vertical height extends. Alternatively, it is also conceivable that all reinforcing elements 14 over the entire vertical height of the rudder blade 2 extend and, for example, to reduce superfluous weight are provided with holes.

FIG. 3 shows a second embodiment of a rudder blade 20 in FIG Cross-section, which like the first embodiment according to FIG. 1 also consists of a body 24 made of elastic material, the is bounded by a profiled outer surface 26. Also with this second embodiment, the same elastic material as in the first version used.

The second embodiment according to FIG. 2 differs from the first one Embodiment according to Figure 1, characterized in that the body 24 in Essentially only by a circumferential outer wall 30 is formed. The also in this embodiment also air and watertight Cavities 28 are on the one hand by first, second and third Reinforcement elements 32, 33 and 34 and on the other hand by a Rudder shaft 36 divided in the plane formed by the rudder blade 20 is located and thus on the vertical height of the rudder blade 20 and extends at right angles to the image viewing plane of Figure 2. Of the Rudder shaft 36 is on both sides of the reinforcing elements 32, 33rd and 34 and via contact surfaces of the rudder stock 36 itself rotatably at the inner wall 30a of the outer wall defining the cavity 28 30, which is usually realized by gluing.

Like the first version is the second version with a Skeleton provided the same tasks as previously in the Can be described in connection with the first embodiment. Unlike the first execution of the skeleton in the second embodiment of the on the inside 30 a of the outer wall 30th adjacent first reinforcing elements 32, along the Symmetry plane extending in the longitudinal direction second Reinforcement elements 33 and extending transversely thereto third Reinforcing elements 34. In particular, the second and third Reinforcing elements 33 and 34 form a truss-like skeleton, which is disposed within the cavity 28. This is the second one Reinforcement element 33 respectively at the front end and at the rear End of the rudder blade 20 connected to the outer wall 30. The first and third reinforcing elements 32 and 34 can over Adhesive joints with the inner side 30 a of the outer wall 30 be connected.

Thus, in the second embodiment, the skeleton is not during of the manufacturing process poured into the body, but in the previously described within the cavity 28. Incidentally, the first to third reinforcing elements 32 to 34 in the second embodiment of the same material as the Reinforcement elements 14 in the first embodiment exist and also to fulfill the same tasks. It is also conceivable, several Arrangements, each in the manner described from the first to third reinforcing elements 32 to 34, in provide different heights within the rudder blade 20, whereby a truss-like skeleton results over the vertical height. In this case, these multiple Gerippeanordnungen thereby be connected to each other, that is at least one of the first to third reinforcing elements 32 to 34 over the entire vertical height extends. Alternatively, it is also conceivable that all the first to third reinforcing elements 32 to 34 over the entire vertical Height of the rudder blade 20 extend and, for example to Reduction of excess weight are provided with holes.

Claims (14)

Hull appendage, in particular keel or rudder (2; 20), for a watercraft, comprising a body (4; 24) bounded by an outer surface (6; 26),
characterized in that the body (4; 24) at least partially on its outer surface (6; 26) comprises elastic material. Hull appendage according to claim 1,
characterized in that the outer surface (6; 26) comprises substantially completely elastic material. A fuselage according to claim 1 or 2,
characterized in that the elastic material is provided as at least one layer on the outer surface. Hull appendage according to at least one of the preceding claims,
characterized in that the outer surface (6; 26) is at least partially formed by the elastic material. A fuselage according to at least one of the preceding claims, wherein the body (4; 24) has an outer wall (10; 30),
characterized in that the outer wall (10; 30) at least partially comprises elastic material. Hull appendage according to at least one of the preceding claims,
characterized in that the body (4; 24) at least partially, preferably completely, consists of elastic material. Hull appendage according to at least one of the preceding claims,
characterized in that the body (4; 24) is provided with at least one reinforcing element (14; 32, 33, 34). Hull appendage according to at least one of the preceding claims,
characterized in that the body (4; 24) contains at least one closed cavity (8; 28) filled with gas, preferably air. Hull appendage according to claim 8,
characterized in that in the body (4) a plurality of cavities (8) behind, arranged side by side and / or one above the other and by wall sections (12) are separated from each other. A fuselage according to claim 8 or 9,
characterized in that the body (4; 24) has at least one wall section (10; 30) of elastic material which delimits on its one side inwardly at least a portion of a cavity (8; 28) and on its other side at least one section the outer surface (6; 26) forms. A fuselage according to claim 7 and according to claim 9 and / or 10,
characterized in that the at least one reinforcing element (14; 32, 33, 34) is fastened to at least one wall section (10, 12; 30). Hull appendage according to claim 11,
characterized in that the at least one reinforcing element (14) is arranged within at least one wall section (10, 12). Hull appendage according to at least one of the preceding claims,
characterized in that the elastic material has a hardness of about 70 to 100 Shore A, preferably 80 to 95 Shore A, and an elongation at break greater than 250%. Hull appendage according to at least one of the preceding claims,
characterized in that the elastic material comprises polyurethane.

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