EP0218260A2 - Speedboat - Google Patents

Abstract

Fast boat which comprises a boat hull having a front stem, a stern, two side walls as well as a bottom plate with a bottom plate surface facing the water, where on the bottom plate surface facing the water on each side respectively one sliding skid is arranged with sliding steps and preferably in the midships plane a keel skid is provided with keel steps, and between the sliding skids at least one aeration channel is formed, the boat hull being preferably equipped with a bow fin, in which the free bottom surface facing the water has primarily in the area between the longitudinal center of the boat and the stern an inclination which preferably declines towards the stern.

Description

The invention relates to a high-speed boat according to the preamble of claim 1.

The purpose of the invention is to influence the dynamic trim, in particular of the high-speed boat known from DE-OS 31 36 715.

This high-speed boat essentially consists of a boat hull of conventional design with a boat wall, a front leg, a stern and a floor, the surface of the floor facing the water, the so-called headliner, being flat. From this water-side floor surface extends downwards at a lateral distance from and symmetrically to the vertical midships plane, a sliding skid beginning in the area of the front edge of the floor and extending to the stern with several sliding steps sloping down to the outside with vertical step side walls and step sliding surfaces arranged perpendicular to it. Each glide level arises with one arranged transversely to the midship level Leading edge and with a flat arch forms a downward and backward sliding surface that merges into a slightly ascending wing. The front edges of the sliding steps are arranged offset to one another in such a way that the sliding step adjacent to the midships plane rises most forward.

In the area of the midships level, a vertically downward keel skid is provided under the headliner surface, which also has stair-shaped keel steps on both sides with front edges arranged transversely to the midships level, vertical side walls and perpendicularly arranged sliding surfaces. The middle keel step begins in the front stem area; the lateral keel steps begin offset to the rear. The keel steps also rise at the front with a flat arch and merge into a step surface that slopes gently upwards and runs at an acute angle or obliquely into the headliner surface, the keel skids ending a little in front of the stern and the keel steps extending downwards in different ways such that the middle keel step extends farthest to the rear. The keel steps are narrower than the sliding steps of the skids.

At the transition between the side walls of the boat and the headliner area or, if applicable, just above or below it, a front fin protruding laterally from the side walls, possibly also projecting forward over the stern, is arranged in the form of a board-like strip, the shape of which - viewed in plan view - is roughly ship-hull-like. The front fin begins like an arch or a pointed arch either in front of the front stem or rises in the area of the front stem, has been standing Lich on both sides and runs into the boat side walls at an acute angle or flat arch. The lower surface of the front fin is preferably in the plane of the headliner surface. The bow fin is intended, in particular, to reduce the ramming movement of the ship as it enters rolling waves.

The arrangement of the skids and the keel skids in combination with the position of the headlining surface results in two side-by-side, separated by the keel skids, tapered towards the rear ventilation ducts, which correspond to the ventilation duct described in DE-PS 20 59 087 form and effect.

From GB-PS 1 199 658 a boat hull with lateral skids with steps stepped outward sliding steps is also known, in which the headliner surface, viewed from the side, begins to run wedge-shaped on the front post and into a flat surface parallel to the waterline up to Aft sky area passes over. The sliding steps arise as in the subject of DE-OS 31 36 715 with a straight edge running at right angles to the midships plane, initially in an arc shape, but then merge into a wedge surface that rises downwards. The sliding steps also start offset to the rear, but end with a vertical trailing edge step, also offset to one another, with the edge that lies further inside, ie, adjacent to the midships plane, ends further forward. Thus, the most internal glide step is the shortest, while the most outer glide step is the longest and extends to the rear.

This design of the skids is not suitable to significantly influence the dynamic trim, because the effective sliding step area of each skid is reduced towards the rear.

The high-speed boat known from DE-OS 31 36 715 has proven itself. At very high speeds, however, the hull still leans so that the stern is lower than the bow, which may be caused by the front fin. However, efforts are made to keep the hull as horizontal as possible, even at maximum speeds, because lower propulsion forces are required. This so-called hydrodynamic trim can only be achieved in known boats due to the spatial shape of the underwater ship up to a certain speed, usually still far from the maximum speed.

The object of the invention is to ensure the hydrodynamic trim up to the maximum speed in a high-speed boat of the type described in the introduction.

This object is achieved, starting from a high-speed boat according to the preamble of claim 1, by the characterizing features of this claim. Advantageous developments of the invention are characterized in the subclaims.

• Fig. 1 eine Seitenansicht des Bootskörpers,
• Fig. 2a, b, c Seitenansichten der Bodenplatte mit Varianten der Keilflächen in der Bodenhimmel­fläche und in den Gleitkufen,
• Fig. 3 eine Seitenansicht des Bootskörpers mit weiteren Varianten von Keilflächen in der Kielkufe,
• Fig. 4 eine Unteransicht der Bodenplatte,
• Fig. 5 eine Seitenansicht des Bootskörpers mit einem Pump-Jet-Antrieb,
• Fig. 6 eine Unteransicht einer bevorzugten Bodenplatte für einen Pump-Jet-Antrieb,
• Fig. 7 einen Querschnitt entlang der Linie VII-VII in Fig. 6,
• Fig. 8 eine perspektivische Ansicht des Bootskörpers,
• Fig. 9a eine schematische Unteransicht des Bootskörpers bis zum Ursprung der Kielkufe,
• Fig. 9b schematisch mehrere Querschnitte durch den Boots­körper ohne Decksaufbauten,
• Fig. 9c schematisch eine Seitenansicht des Bootskörpers ohne Decksaufbauten.

The invention is explained in more detail by way of example with reference to the drawing. Show it:

• 1 is a side view of the hull,
• 2a, b, c side views of the base plate with variants of the wedge surfaces in the headliner surface and in the skids,
• 3 shows a side view of the hull with further variants of wedge surfaces in the keel runner,
• 4 is a bottom view of the base plate,
• 5 is a side view of the hull with a pump jet drive,
• 6 is a bottom view of a preferred base plate for a pump jet drive,
• 7 shows a cross section along the line VII-VII in FIG. 6,
• 8 is a perspective view of the hull,
• 9a is a schematic bottom view of the hull to the origin of the keel runner,
• 9b schematically shows several cross sections through the hull without deck structures,
• Fig. 9c schematically shows a side view of the hull without deck structures.

The high-speed boat shown has a hull with a front strut 1, a stern 2, the two boat side walls 3 and the bottom plate 4 with the headlining surface 5. On each side, next to and at a distance from the midships level (not shown), there is a skid 6. The two skids 6 are arranged mirror-symmetrically to the midships level and each have several, for example, four levels 6a, b, c, d (Fig. 1, 3 , 4). The glide levels 6a, b, c, d arise in the bow area from the Floor sky surface 5 in an edge 7 arranged transversely to the midships plane and with an obliquely, preferably flat-arch, arch 7a projecting downwards and merging into a horizontal part 7b. The sliding steps have at least one vertical side surface 8 and a sliding surface 9 arranged perpendicular thereto. When viewed in cross-section, the sliding steps are offset from one another in a staircase-like manner, with the step located further inwards projecting lower. The original edges 7 are staggered towards the rear, in that the sliding step, which is located further inside, rises further forward. The sliding steps preferably run to the rear 2.

In the area of the midships, a keel runner 10 with keel steps 11 is provided under the headlining surface 5. The front edges 12 of all keel steps 11 preferably originate side by side, the middle keel step 11a starting with a deeper, convex arch 13a and the keel step 11b arranged next to it with a flatter arch 13b. The keel steps, like the sliding steps, have at least one vertical side surface 14 and in each case one sliding surface 15 arranged transversely thereto. The keel step 11a runs in the back in a wedge shape into the two keel steps 13b, so that a wider keel step surface 16 results thereafter, this wider keel step in turn wedge-shaped opening into the headliner surface 5. In the same way, the sliding step 6a can also run into the sliding step 6b, which results in the wider surface 17. The outermost sliding step 6d is preferably aligned approximately vertically with the boat side wall 3a or 3b.

A ventilation duct 20, which is described, for example, in DE-PS 20 59 087, is formed between each sliding skid 6 and the keel skid 10.

On the hull, in the area of the front step 1 and the side walls 3a, b, a front fin 18 projecting from the side walls of the type described in DE-OS 31 36 715 is provided. The front fin 18 can spring from the front stem 1 and extend in a pointed or arched shape sideways to the rear and run in a wedge shape into the boat wall 3a, b (FIG. 8). But it can also start projecting from the front stem (Fig. 1, 3, 5). Furthermore, it can be designed as an extension or widening of the base plate 4 in the front area, wherein the keel skids and the skids can extend onto the lower surface of the front fin 18.

It is essential that the free headliner area in the area between the center of the boat and the stern has a slope 19 which slopes down to the stern, which preferably arises without edges in the headliner area and is flat or sloping in a concave shape. When the flow starts against the slope 19, a buoyancy force is generated which increases with the speed of the flow and levers the stern out of the water. The length and area size of the bevel 19 and their wedge angle β (FIG. 2a) are based on the wedge angle α and the length and area size of the run-up bevels 7a, 13a, 13b of the sliding steps 6a, 6, c, d and the keel steps 11a, 11b and on the wedge-shaped design of the ventilation ducts 20, but in particular also on the size of the surface of the front fin 18 agreed that the boat is automatically balanced at almost all speeds, ie the boat always assumes a horizontal swimming position or a predetermined, slightly different swimming position. The buoyancy force generated by the flow pressing against the run-up slopes of the runners and the ventilation ducts essentially acts on the foredeck, while the buoyancy force generated by the flow pressing against the bevel 19 acts on the stern area of the boat and compensates for the former buoyancy force. The dynamic center of buoyancy automatically remains at the point where the point of attack for a horizontal swimming position of the boat lies. When the boat is in a horizontal swimming position, the boat is raised further out of the water with increasing speed or with increasing flow force. It is surprising that the boat does not "suck up" with the stern at high speeds.

To support the effect of the slope 19, a slope 21 can also be provided in the rear region of the sliding steps (FIGS. 1, 2c). FIGS. 2a and 2b, on the other hand, show ascending (FIG. 2a) and horizontal (FIG. 2b) run of skids in the rear area. The bevels 21 are particularly effective when two or more skids 6a, b, c, d merge into one another in the rear area and e.g. form the larger surface 17 (Fig. 4).

In a further embodiment of the invention, the keel runner also merges into a sloping bevel 22 in its rear region, so that there is an upward jumping rear edge 23 (FIGS. 3, 4).

Mainly, however, the slope 19 according to the invention compensates for the additional lift generated by the front fin when exposed to a current.

The slopes 21 impart a synergistic effect to the desired buoyancy; because these slants support the effect of the rudder of the boat considerably. The sliding steps create a water displacement transversely to the direction of travel to the outside in the manner of a cascade waterfall. This cascade effect is particularly strong in the area of the slopes 21. Accordingly, the counterforce acting on the boat from the side is also greater than further ahead. As is known, when the rudder is turned, the boat first turns, i.e. to where it should go. Only then does the centrifugal force work and tilts the boat out of the curve in the opposite direction. In the first phase of inclination, when the boat leans into the curve, a higher cascade effect is created on the curve side and, as a result, a higher force is exerted on the boat from the outside, transverse to the direction of travel, which pushes the boat to the side in the stern area and thus the Rudder effect supported. The boat turns faster and with a smaller radius.

According to a special embodiment of the invention, which is not shown because it is easy to imagine, a device is provided which carries the bevel 19, this device being pivotable downwards on the floor about a horizontal axis arranged transversely to the midships plane, preferably at the beginning of the bevel 19 the boat is arranged, for example, as a wedge-shaped Additional part that can be adjusted by mechanical or motor means in such a way that the bevel 19 can be pivoted deeper downwards. This enables the buoyancy to be adjusted to, for example, other loading situations on the boat.

Another embodiment of the invention provides the same configuration for the sliding steps and, if appropriate, also for the keel steps.

The high-speed boat according to the invention is also particularly suitable for equipping with a pump jet drive known per se. A pump jet drive sucks the water in via an impeller under the ship's floor. Energy is applied to the water in a bend to be expelled again at an angle of approximately 15 ° below the vehicle floor. The pump jet drive is installed in a so-called well, the lower edge of which is flush with the ship's bottom. The engine power is converted into thrust, which is available for propulsion and control in any direction at the same time. Vehicles equipped with a pump jet drive are extremely manoeuvrable. Up to now, equipping high-speed boats with a pump-jet drive was problematic because not enough water pressure is generated on the vehicle floor on these boats. However, the bevel 19, in particular the adjustable bevel, increases the pressure, so that optimal conditions are created for the operation of a pump jet drive. 5 shows an example of the arrangement of a pump jet drive 24 in the high-speed boat according to the invention.

FIGS. 6 and 7 show a special design of the skids 6, which is particularly suitable when using two pump jet drives arranged in the rear region of the skids. It is a slide step 6b which is wider than the other skids and in the rear area of which a pump jet drive 24 is arranged. The sliding step 6b has the slope 21 described. On the two outer edges of the sliding step are arranged vertically downward, starting approximately in the longitudinal center, extending to the rear, wedge-shaped water guiding webs 25, which cause a higher flow rate, so that the water pressure in the area of the drives 24 is thereby additionally increased. The webs 25 end shortly before the pump jet drives 24. It is particularly advantageous if, following the webs 25, the bevel 21 is designed to be even steeper than before (not shown).

It is useful that the slopes 19 and 21, 22 result not only from a slope of the channel roof in the front area of the boat, but in the longitudinal center area e.g. spring from the bottom plate 4 of the boat. When viewed from the side, the result is e.g. for example a sine curve if the front canal roof is convexly arched, or a steeper slope bent downwards if the front canal roof runs obliquely downwards.

1, 2a, b, c, 3, 5 and 9c schematically show side views, the bevel 19, which would normally not be seen in the side view, is shown in an excellent line so that the invention can be better illustrated.

9a, b, c show essential features of the invention. The static state of swimming is shown, ie the position of the boat at a standstill on the water. The weight of the boat is designed in combination with the buoyancy forces that act against the underwater ship so that the front bevels (angle α) or at least partial areas of the bevels of the keel skids 10 and the skids 6 positioned above the water line 26 (Fig. 9c) and then immerse in the water in the area between the front edge and the longitudinal center of the base plate 4. In the area of the longitudinal center of the base plate 4, all runners are under water. In addition, the canal roof or the front headlining surface 5 is located from the front edge of the base plate 4 to approximately the longitudinal center of the base plate 4 above the water line 26 and forms with the water line 26 a wedge space that tapers to the longitudinal center of the base plate 4. Following the immersion of the canal roof or the headliner surface 5 in the water, the headliner surface 5 continues as a slope 19 backwards to the end of the base plate 4. FIG. 9c also ideally shows a somewhat lower water line 26a, which is located at high speed results. It is essential that the slope 19 still extends below the water line 26a, that is, is wetted by the water. The floating position of the boat is shown schematically in Fig. 9b. These are schematic cross sections at the location of the hull opposite to the location in FIG. 9c. FIGS. 9a, b and c belong together insofar as FIG. 9b shows a cross section in each case at the location that is at the same height in the drawing 9a and 9c. It can be seen that the slope 19 is always positioned at least with partial areas under water and that at least one outer step of the skids 6 are arranged above the water line 26. The upper cross-sectional view shows this state in comparison to the lower cross-sectional view in FIG. 9b. The skid step 6d is above the water line, while the slope 19 is in the water.

This arrangement of the runners for arranging the bevel 19 ensures that the hull is levered out if the dynamic pressure acts on the bevel 19 during the journey and the hull is tipped forward. The water then hits the surface of the runner 6d which has not yet been wetted and generates a compensating buoyancy, so that the boat is lifted further out of the water in an almost horizontal position, i.e. that the water line is shifted down (water line 26a).

If the bevel 19 is positioned under water, it also counteracts the heeling of the boat, because the dynamic pressure of the water when the boat is driving has a greater effect on the transversely tilted surface of the bevel 19.

According to a preferred embodiment of the invention, the edges of the runners 10 and 6 run parallel to the midships plane.

Claims (18)

1.High-speed boat, which has a hull with a front strut, a stern, two side walls and a base plate with a headlining surface, with a skid with sliding steps and preferably a keel skid with keel steps being arranged on the side of the headlining surface, and between the Skids at least one ventilation duct is formed, and wherein the hull is preferably equipped with a front fin, characterized in that the free headliner surface (5) has a slope (19) preferably falling to the stern, mainly in the area between the center of the boat and the stern. 2. High-speed boat according to claim 1, characterized in that the slope (19) rises without edges in the headliner surface (5). 3. High-speed boat according to claim 1 and / or 2, characterized in that the bevel (19) is composed of several rows of bevels, each subsequent bevel having a larger angle β than the previous one. 4. High-speed boat according to claim 1 and / or 2, characterized in that the slope (19) is concave-arcuate. 5. High-speed boat according to one or more of claims 1 to 4, characterized in that the wedge angle β of the slope (19) corresponds approximately to the wedge angle α of the sliding steps (6a, b, c, d). 6. High-speed boat according to one or more of claims 1 to 5, characterized in that in the stern area at least one sliding step (6a, b, c, d) a slope (21) is arranged. 7. High-speed boat according to claim 6, characterized in that two or more sliding steps (6a, b, c, d) merge into each other without edges in the stern area and form a larger area (17). 8. High-speed boat according to one or more of claims 1 to 7, characterized in that the keel runner (10) has a sloping slope (22) with an upward trailing rear edge (23) in the rear region. 9. High-speed boat according to one or more of claims 1 to 8, characterized in that the slope (19) on a front Direction is arranged, which is arranged about a horizontal, transversely to the midships plane, preferably at the beginning of the slope, pivotable downward on the bottom of the boat. 10. High-speed boat according to claim 9, characterized in that the bevel is arranged on a wedge-shaped additional part which can be pivoted mechanically or by motor. 11. High-speed boat according to one or more of claims 1 to 10, characterized in that it is equipped in the stern area with at least one pump jet drive (24). 12. High-speed boat according to one or more of claims 1 to 11, characterized in that at least one sliding step (6a, b, c, d) on its two outer edges a vertically downwardly extending, starting approximately in the longitudinal center, running to the rear , has a wedge-shaped water guide (25). 13. High-speed boat according to one or more of claims 1 to 12, characterized in that the slopes (19, 21 and 22) to the slopes in the bow part of the boat - viewed from the side - are steeper downwards. 14. High-speed boat according to one or more of claims 1 to 13, characterized in that in the static and / or dynamic swimming state of the boat, the weight of the boat in combination with the buoyancy forces acting against the underwater ship is designed so that the front Sloping run-up slopes or at least partial areas of the run-up slants of the keel skids (10) and the skids (6) are positioned above the water line (26) and then immersed in the water in the area between the front edge and the longitudinal center of the base plate (4), and that the previous headlining surface (5) from the front edge of the base plate (4) to about the longitudinal center of the base plate (4) above the water line (26) and with the water line (26) forms a tapering wedge space to the longitudinal center of the base plate (4), and that following the immersion of the canal roof or the headliner surface (5) in the water, the headliner surface (5) as a slope (19) further back to end of the base plate (4) runs. 15. High-speed boat according to one or more of claims 1 to 14, characterized in that the slope (19) is always arranged under water both in the static swimming state and in the dynamic swimming state. 16. High-speed boat according to claim 14 and / or 15, characterized in that the slope (19) is always positioned at least with partial areas under water. 17. High-speed boat according to one or more of claims 14 to 16, characterized in that at least one outer sliding step (6d) of the skids (6) is arranged above the water line (26). 18. High-speed boat according to one or more of claims 1 to 17, characterized in that the longitudinal edges of the runners (10 and 6) or their steps run parallel to the midships plane.

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