The invention relates to a surfboard having a hull component with a receptacle at the stern end, a drive unit which fits into the receptacle at the stern end in a positively locking manner and a gap between the hull component and the drive unit on the underwater surface.
Inflatable surfboards with a drive unit are known in the prior art for example from DE 10 2015 103 503.0. The known surfboard has an inflatable hull component with a recess at the stern end as well as a drive unit which fits into the recess at the stern end in a positively locking manner and is inserted into it. A gap on the underwater surface is formed between the drive unit and the hull component. The surfboard driven by the drive unit can reach considerable speeds of 25 knots and more during the ride. This results in a water current along the underwater surface of the surfboard and a water pressure on the underwater surface of the surfboard which forces water into the gap. As a result the positively locking connection between the hull component and the drive unit is loosened, so that the water resistance of the board is unnecessarily increased and the positive locking is significantly impaired.
DE 10 2015 103 863 A1 discloses a surfboard having a two-part drive component which can be releasably fastened at the stern end to an inflatable hull component by fastening means. The contours of the two-part drive component and of the hull component are adapted to one another in a complementary manner. This has fundamentally the same problems as the aforementioned prior art.
It is an object of the present invention to provide an inflatable surfboard which avoids or at least reduces the above-mentioned disadvantages.
This object is achieved by a surfboard referred to in the introduction with the features of claim 1.
Preferred embodiments are the subject matter of the subordinate claims.
The surfboard according to the invention comprises a hull component with a recess at the stern end, a drive unit which fits into the recess at the at the stern end in a positively locking manner and is preferably already inserted into it, and a gap on the underwater surface between the hull component and the drive unit, wherein an overlap which covers at least sections of the gap is arranged on the underwater surface of the hull component.
It has been shown that the ingress of water into the slot can be effectively reduced if an overlap which covers at least sections of the gap is arranged on the underwater surface of the hull component. It is not absolutely necessary to achieve a watertight closure relative to the surrounding water. However, the function of the overlap is that during the ride, that is to say when a water current forms along the underwater surface of the surfboard, this water current can no longer penetrate into the gap, but is led away along the underwater surface via the gap. Thus the penetration of water into the gap is largely prevented, and in addition a slight suction effect can take place at the open end of the overlap, which to some extent even sucks out the water located in the gap.
The hull component advantageously has two lateral arms which preferably engage in a U shape around the drive unit. The overlap is adapted to the configuration of the gap, and the overlap therefore likewise has a U-shaped configuration and covers at least the section of the gap at the bow end. In the past, most water penetrated into the gap in the section of the gap arranged transversely, preferably perpendicularly with respect to the direction of travel at the bow end. This can be effectively prevented. The expression “U-shaped” should be understood in general terms here. However, a U shape should be understood as strictly a U shape but also a dish shape, a rectangular shape or the like.
The hull component is preferably designed to be inflatable. In particular, with inflatable hull components, the penetration of water into the gap leads to a widening of the gap and an increase in the drag, because the hull component yields to some extent under the pressure of the penetrating water.
The hull component can be made from a drop stitch material and is firmly inflatable. The lateral walls of the hull component have a rounded outwardly projecting configuration, that is to say a convex configuration. This convex shape of the hull component forms more or less automatically as a result of air being introduced at high pressure into the hull component. The peripheral lateral walls of the drive unit correspondingly have a concave configuration. The width and length of the drive unit are chosen so that it fits into the recess in a positively locking manner. In spite of precise adaptation of the lateral walls of the drive unit to the inflated hull component, nevertheless a gap forms in particular exactly on the underwater surface between the hull component and the drive unit. Water is forced into this gap during the ride.
In particular a section of the gap extending transversely in the direction of travel is covered according to the invention by the overlap. The overlap preferably covers the entire transversely extending section of the U-shaped gap and covers at least part of the U-shaped lateral branches of the gap. The overlap on the edge remote from the recess is preferably connected as smoothly as possible to the underwater surface of the hull component, that is to say for example chamfered, and is glued or sewn directly on the edge, in particular the leading edge in the direction of travel of the surfboard so that, even in the event of a relatively strong current, water cannot penetrate between the leading edge of the overlap and the hull component and advantageously the water resistance of the board is not increased by the edge.
In a further favourable embodiment of the invention a releasable fastening means is arranged between an inner side of the overlap facing the drive unit and the underwater surface of the drive unit.
Here and in what follows, “inner” relates to the orientation towards the drive unit or towards the U-shaped recess. On the side of the overlap facing the drive unit a releasable connection, for example a hook-and-loop fastener, can be arranged along an inner side of the overlap, and interacts with a hook-and-loop fastener counterpart arranged on the underwater surface of the drive unit, so that the overlap is also additionally fastened at least releasably to the drive unit. As a result the penetration of water can be further reduced and the danger of increasing the water resistance of the board by the overlap can likewise be reduced.
In order that a minimal additional flow resistance is produced and the overlap covers the gap as favourably as possible, at least one fastening line is provided between the overlap and the hull component, wherein advantageously a nominal dimension of the fastening line of the hull component is greater than a nominal dimension of the fastening line of the overlap. Thus the fastening lines of the hull component and the overlap are not exactly identical, but because the fastening line of the hull component is somewhat greater than that of the overlap, an insertion of the drive unit into the hull component at the outset in the non-inflated state is easily possible, and the overlap is spanned smoothly when the hull component is firmly inflated. In this way creasing is counteracted.
The overlap is preferably open towards the stern end. The overlap which is open towards the stern end has the advantage that an at least slight Bernoulli effect can be produced due to the water current flowing along the overlap and past the drive component and also more or less draws water out of the gap.
The invention is described with reference to an embodiment in six drawings. In the drawings:
The hull component 2 can preferably be made from a drop stitch material. The drop stitch material is produced by the drop stitch method, wherein two or more synthetic fabric webs, preferably denier polyester fabric webs, are laid one above the other. The two synthetic fabric webs are connected to one another by a plurality, i.e. thousands, of polyester threads. In this case the maximum spacing of the two fabric webs is fixed, so that the space between the fabric webs which is filled with polyester can be filled later with compressed air and the fabric webs are then substantially parallel to one another. The polyester threads are sewn on both sides to the two fabric webs, for example with the aid of a drop stitch sewing machine. The two fabric webs which are sewn to one another form the support structure which gives the hull component 2 its mechanical strength in the inflated state.
The two fabric webs which are connected to one another are cut to the required shape. The upper and the lower fabric webs are preferably coated with PVC layers, preferably with three layers, and are pressed and glued in layers. The faces are glued, overlapping, to the seam strip and are pressed, so that the airtight hull component 2 is produced.
The drop stitch method makes it possible to produce the inflatable hull component 2 with outstanding mechanical strength properties, which withstand not only tensile loads but also compressive loads and shearing loads. The drop stitch outer skin of the inflatable hull component 2 is airtight and in the inflated state is exceptionally resistant to deformation, so that a surfer can stand and surf on the hull component 2 whilst retaining the external shape of the inflated hull component 2. The inflatable hull component 2 is filled with air under high pressure. The filling can take place by means of an air pump or a compressor. The compressor can be supplied with electrical power by batteries incorporated in the surfboard 1.
The hull component 2 made from the drop stitch material is preferably sound-damping, so that the volume of sound generated by the breaking of waves, but also by the drive, is damped by the hull. The hull component 2 is subject to little vibration during operation, because vibrations are reduced by the drop stitch material. Since the hull component 2 is somewhat deformable, impacts and waves etc. are advantageously absorbed. Furthermore, by comparison with conventional surfboards 1 it is advantageous that the softer hull causes fewer injuries, for example if the surfboard 1 collides with the surfer in the event of the surfer falling off.
The stern region of the hull component 2 includes the receptacle 4 for the drive unit 3. The drive unit 3 can comprise a jet drive. The jet drive comprises an opening for the water inlet on an underwater surface 7 of the drive unit 3 as well as a water channel towards the stern end surface of the drive unit 3. The water outlet can be formed there by a nozzle. The nozzle can be arranged pivotably or fixed.
In the water channel a rotor is provided which, due to its high rotational speed in operation, draws water into the water channel and sprays it out rearwards through the nozzle and thus gives the surfboard 1 the propulsion. The rotor is connected by means of a drive train to a motor, preferably an electric motor which is optionally controllable by means of a controller and is supplied with power by means of the battery. The drive unit 3 as a whole is replaceable. The term “rotor” should be understood broadly here. It may be a propeller, an impeller or the like.
A gap 6 is produced between the drive unit 3 and the hull component 2. Since the hull component 2 has a convex configuration into the receptacle 4 along a lateral inner wall running around about three-quarters of the drive unit 3, an outer periphery of the drive unit 3 is adapted in a positively locking manner to this contour, but this adaptation may never be so exact that no gap 6 is produced, in particular not directly on the underwater surface 7, on the joint between the hull component 2 and the drive unit 3. In the illustration in
The overlap 8 preferably rests closely and without creases on the underwater surface 7 of the drive unit 3.
Number | Date | Country | Kind |
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10 2017 130 959.4 | Dec 2017 | DE | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2018/086146 | 12/20/2018 | WO | 00 |