DE2749362B2 - Boat hull with a displacement keel below the waterline on each side - Google Patents

Description

The invention relates to a boat hull with one arranged below the waterline on each side of the board Displacement keel, which has an approximately triangular cross-section with a concave Underside and extends over a considerable part of the length of the boat.

Such a boat hull is known from US Pat. No. 2,677,139

It is also known that the cross property

of a sailing vehicle is decisive for the design the underwater lateral surface is affected, after

s measurements from Gilgenast turned out to be the The hull of a keel yacht only contributes around 30% to the necessary lateral buoyancy and around 70% applied by the keel fin.

With the propulsion resistance, however, it is the other way round, here about 75% and on the keel fin about 25%. It is also known that keel fins with a high aspect ratio have a have greater lateral buoyancy with less drag than keel fins with a low aspect ratio.

The stability of sailing vehicles has a decisive influence on the sail carrying capacity and thus not only on the behavior when heeling due to wind pressure, but also on the achievable speed. Today, fast boats predominantly use wide, round-ribbed ship shapes with a divided underwater lateral plan and narrow, deep keel fins or swords. The ballast portion of keel boats is approx. 40% to 50% of the empty weight.

Conventional vehicles with fixed keel keels or rafts have the advantage of being upright When standing on firm ground, the sailing characteristics are usually less favorable than those of the larger surface and the low aspect ratio of the keels as well as the lack of adaptation of the keels to the changing ones Flow conditions on the ship's hull arises. In addition, these vehicles are mostly used for tidal waters designed for which a large draft is undesirable and with poorer sailing properties is bought.

It is therefore the object of the invention to improve the sailing properties of flat-sailing sailboats that are equipped with Consideration for an area with shallow water depths are designed to improve.

To solve this problem, a boat hull of the type mentioned is proposed, which according to the Invention has the features mentioned in the characterizing part of claim 1.

The advantages achieved by the invention are in particular that the lateral buoyancy of a The hull of the sailing vehicle with the help of the displacement keel keels with increasing heel is increased crucially and thereby an improvement in Cross properties enabled. The fin keels necessary to achieve optimal cruising properties or swords can be reduced very much in terms of area. In this way it is possible, totz low hull draft to achieve good cruising properties. By reducing the fin keel resp.

5- Sword area becomes a speed increase enables.

Due to the wave interference of the bow wave system with the wave system of the displacement keel keel there is a reduction in the wave resistance that

w) also leads to an increase in speed.

The high dimensional stability achieved by the W-shaped cross-section of the boat hull increases this Sail carrying capacity and enables a considerable reduction of the ballast weight in overturning vehicles

M quantity. This increases the speed of the vehicle especially increased in light winds. The one in flat-bottomed vehicles when driving in a trough of waves occurring loss of stability, which lead to capsizing

can does not occur.

In addition, the vehicle has the known advantage of conventional keel keelers, sword boats and Flat-bottomed vehicles like standing upright in the dry fallen Condition even on less firm ground. Another advantage over vehicles with a central keel consists in getting stuck on the ground when sailing close to the wind in a wreathed position can not occur, since the torso depth is with decreasing heel decreased instead of increased as with the central keel.

The lack of liveliness in many vehicles when sailing close to the wind with increasing Heeling, which occurs especially in wide, flat vehicles with full aft hulls and to one Loss of speed will result with the help of the displacement keel keels due to their larger size Cornering force and directional stability effectively avoided.

The criticized especially in flat walking around span term vehicles with caught-up swords or vehicles with short, deep keel strong roles on downwind courses due to the lack Unterwasserlateralfläche is largely avoided-Kimmkiele displacement by the use of, as they 2 ·> without the Unterwasserlateralfläche to increase as bilge keels take effect at a convenient distance from the roll axis.

The enlargement of the The leeward angle becomes more and more effective with increasing heel Displacement keel with an increase in the lateral buoyancy force up to heel angles of 30 ° avoided.

For the interior of a sailing vehicle 3ί the arrangement of displacement keel keel creates new room design options, because with unchanged external dimensions, more volume for deep storage spaces and one better usable form with a larger base area to arise. It can do this even with smaller ones Boats already have berths arranged one above the other with sufficient space in between. The displacement keels allow the installation of deep-set swords that do not affect the interior affect. The ballast required in kernel-safe vehicles can be removed over a large area inside be distributed to both displacement keel kills so as not to concentrate the inertial forces and the To increase the radius of gyration around the longitudinal axis, w This reduces the stress on the fuselage and an improvement in rolling behavior brought about by the elongated to the ends increasing shape of the displacement keels, a cornering force is exerted on the fuselage, which the course stability improves without deteriorating the swiveling wedge. Due to the larger floor area of the Fuselage with the inclined front inner surfaces and the sharp tear-off edges in the rear part of the Displacement keels improve the gliding properties of the vehicle

Advantageous further refinements of the invention are characterized in the subclaims.

An embodiment of the invention is shown in the drawing and will be explained below with reference to described in more detail in this drawing

In Fig. 1, the shape of the displacement keel keel is shown in the side view, with curve (B) the upper inlet line in the fuselage, curve (F) the lower boundary line of the displacement keel keel and the almost vertical one, only in a direction toward the vessel ends, inwardly curved surface (I) (hatched) the outside of the displacement K represents immkieles.

In Fig. 2, the main bulkhead cross-section of the boat hull with the two displacement keel keels on the port and starboard side (hatched) is shown. The surface (I) shows the almost vertical outside, the surface (K) the downward and inward curved underside of the displacement keel.

In Figure 3 an embodiment of the inclination of the outside (I) is given up to a maximum of 15 ° from the vertical to the outside.

In Fig. 4 an embodiment of the inclination of the outside (I) up to a maximum of 5 ° inward is given. This cross-section is particularly suitable for smaller GRP boats that are to be demolded in one piece.

F i g. 5 shows the special shape of the stern frame (port side v. 0-4) of the displacement keel (hatched) with the characteristic sharp V-shape on the underside of the keel.

Fig.b shows the special shape of the foredeck frames (Bb-Scitc v. 5-10) of the displacement keel keel (hatched) with the characteristic rounded one Bottom. It should be noted here that the radius of the underside increases towards the front.

F i g. 7 represents the in F i g. 5 and 6 indicated section .V-Xdar, which is inclined at 15 ° to the horizontal the displacement keel (port side) is guided. This is the airfoil profile shape of the displacement keel to recognize, which becomes effective with increasing heel. The suction side of the profile points to Wind direction and the pressure side of the profile points to the direction of flow of the water when sailing close to the wind.

For this purpose 2 sheets of drawings

Claims (6)

Patent claims: 1. Boat hull with a displacement keel keel arranged on each side below the waterline, which has an approximately triangular cross-section with a concavely curved underside and extends over a considerable part of the length of the boat, characterized in that the underside of the displacement keel keel at its deepest Place has a contour (L) that comes close to the half-oscillation of a sine curve, the half-wave length of which corresponds to the distance of the lowest point on the underside of the keel from the inlet of the keel into the horizontal boat bottom and whose double amplitude value corresponds to the keel depths (H) below the horizontal boat bottom, where the underside length (M) of the keel is 80% of the largest half-width of the boat (TV ^ (see Figs. 2 to 4). 2. Boat hull according to claim 1, characterized in that the length (A) of the displacement keel, starting at the rear end of the construction waterline (DWL) , is 95% of the construction waterline length (see FIG. 1). 3. Boat hull according to claim 1, characterized in that the upper inlet line (B) of the displacement keel keel in the boat hull, seen from the side, approximates the shape of a trochoidal wave, the wave height (D) of which is approximately 7% of the boat's length (C) and whose greatest distance (E) from the construction waterline (DWL) is 5% of the wavelength (C) (see Fig. 1). 4. Boat hull according to claim 1, characterized in that the lower boundary line (F) of the displacement keel keel has the shape of a flat parabola, the lowest point of which lies on half the length of the construction waterline (DWL) and the largest distance (G) from the Construction waterline (DWL) corresponds to twice the value of the keel depth (^ (see Figs. 1 and 2). 5. Boat hull according to claim 1, characterized in that the crescent-shaped outside (I) of the displacement keel, standing almost vertically, inclined within the limits of 15 ° outward to 5 ° inward and only in one direction from its widest point the ends of the ship is curved inward. 6. Boat hull according to claim 1, characterized in that a section guided at 15 ° to the horizontal in the waterline plane through the displacement keel takes the form of an asymmetrical airfoil, the greatest thickness (O) of which is about 40% of its length (P) from the front is measured, whose thickness (O) is approx. 15% of its length (P) and whose chord is at an angle of 2 ° to 3 ° to the vertical central aisle plane (see FIG. 7).