LT3281B - Multiple-hull with limited righting moment and transverse rectifying torque with reduced advanced resistance - Google Patents

Abstract

The multiple-hulled ship comprising a central float with a large length:width ratio connected by load-bearing connection means (1) with side floats (2, 3) is characterised in that the side floats possess permanently submerged portions whose buoyancy is so calculated as to exert on the connecting means, in still water, an Archimedean thrust less than or no greater than that exerted on these means by the central float. <IMAGE>

Description

The present invention is directed to high speed multi-hull vessels used for a variety of purposes, e.g. for underwater parts of merchant, military and / or pleasure craft.

High-speed vessels are known to require very long hull-to-hull ratios, but once this high is reached, the hull becomes completely unstable and, of course, unusable.

To overcome this disadvantage, there is a known technique in the art for using side floats, for example, ships known as trimarans have two or more side floats.

The disadvantage of Trimaran type vessels is that the torque for very small corners of the crane is very high compared to a single hull classical ship. This causes the boat to become uncomfortable, more effort is needed to improve its construction, and low-impact shocks to the water occur.

The invention solves the above problem by using a center float of high length-to-width ratio in trimaran type vessels as well as lateral buoys which, depending on the angle of the crane, produce gradual return moments analogous to the alignment of single hull vessels.

According to the invention, a multi-hull ship with a limited transverse alignment moment having a central buoy connected to at least two lateral buoys, characterized in that any horizontal section located at an altitude of at least 6% between the float axes and the ship's axis is above or below any waterline of the vessel, the horizontal cross-sectional shape of the side buoys shall be such that the sum of the square cross-sectional areas of each float from its axis and the axis of its vessel, in meters, does not exceed 80 % of the ship's weight in metric tonnes from the sum of the number 4 and the distance between the center of the displacement vessel and the center of gravity of the vessel; at least one lateral float on each side of the central float being partially submerged at zero speed; and in that the center-float width-to-draft ratio for any navigable waterline is at least 1 and the length-to-width ratio is at least 8.

If these conditions are met, the ship becomes comfortable to operate and suitable for the carriage of passengers and cargo that requires careful handling.

In addition, comfort is further enhanced by the addition of stabilizers on the inside of the side buoys. The feature of the invention which gives the ship a torque dependent on the angle of the horn, which is clearly smaller than that of other multi-hull vessels, enables the installation of small surface stabilizers and, at the same time, low resistance to movement. Finally, there is no need to make them retractable, which reduces their cost, considering the ability to position them on the inner surface of the side buoys.

Other features of the invention will be set forth in the following detailed description.

Embodiments of the embodiment of the invention are illustrated by way of non-limiting examples in the accompanying drawings.

Fig. - a side view of the vessel of the invention;

Fig. - front view of the same vessel;

and Figure 4. - diagrams showing the special shapes the side stabilizing hulls may have;

Fig. - a schematic view of the section along line V-V in Figure 3, showing that the horizontal sections of some hulls may have a special shape;

Fig. - diagram of the ship according to the invention (top view) with different number of lateral buoys;

and Figure 8. - diagrams showing the special characteristics that the side stabilizing hulls may have;

Fig. - an embodiment of the embodiment analogous to the one in Figure 1;

Fig. - a front view corresponding to Figure 9;

and Figure 12. - schematic representations showing special implementations.

The ship shown in the drawing has a platform 1 supported by a center float 2 connected to the side buoys 3, 4. Platform 1 is provided for communication with the side buoys 3, 4.

in the drawing, platform 1 supports a rigid structure la. forming the brackets or arches lb connecting with the side buoys.

The central float 2, or hull at least at the waterline level and for any sailing condition, has a large length to width ratio. This ratio shall be equal to or greater than 8. For example, for a ship of more than 100 meters in length, the width of the center buoy along the waterline shall be approximately 8 meters at midline level.

According to the invention, in order to prevent the ship from tilting when stopped, it is necessary that at least one of the center buoys, or at least one side buoy, is partially submerged at zero speed.

The side buoys shall consist of stabilizers and shall be designed so as to have a low total displacement which shall not exceed 20% of the total displacement of the vessel. In addition, the submerged float shall have a low immersion surface and, at best, not more than 15% of the total immersion surface of the vessel. In addition, in the static position, the initial effective length of the lateral floats 3, 4 is at best equal to a maximum of 40% of the length of the central float 2 along the waterline. The center-float width to draft ratio should be greater than 1 at any waterline level and navigational conditions, i.e. at any waterline while the ship is in motion.

The essence of the invention is that any horizontal section within the area above the height of at least 6% of the distance between the lateral float axis x and the central float axis X above or below any of the ship's waterline while the vessel is in motion , that for the whole set of these floats the sum of the square sections of each float in square meters between its x-axis and the X-axis of the vessel does not exceed 80% of its weight in metric tonnes, between the displacement center B and the vessel's center of gravity G expressed in meters.

In other words, the ship must satisfy inequality n

Σ Sidi ² <0.8Δ (4 + BG), i = 1 where:

n - number of lateral shells;

Si is the horizontal sectional surface of the i-th hull in the waterline;

di is the lateral distance between the longitudinal axis of the i-th hull and the longitudinal axis of the vessel;

Δ - displacement or weight of the vessel;

- stability module;

BG is the distance between the displacement center B and the center of gravity G of the vessel

In view of the above, it is apparent that the shape of the horizontal cross-section of the lateral buoys may vary depending on specific navigation conditions and design features. Figure ³ shows that the side buoys, for example the buoy 3 of the profile, are substantially rectangular in shape and have a horizontal cross-section VV in the form of a rectangle with slightly rounded and flattened sides for proper hydrodynamic properties. The ovoid or wing shape is well suited for hydrodynamics.

The figure shows that the lateral floats from the profile can be of complex shape, for example, a part on either side of the waterline F - substantially rectangular in the form of R _x , passing at the forward part of the stem 20 to the sloping part 21.

the figure shows that the lateral buoys may have a substantially trapezoidal submerged portion T, inclined to the nose 22.

the figure shows that lateral buoys can restrict two adjacent volumes without a gradual transition.

and Figures 8 show that the side floats can be made up of two unmounted volumes.

Other profile shapes can be used as long as they do not change the above conditions, that is, if the shape does not provide a high leveling torque at low corners of the crown, but that this torque increases with the crown angle, ie the group would be at the level of increasing buoyancy:

- Level 1 for small corners of the horn, with the first level of buoyancy acting on each side buoy;

- Level 2 - For larger corners of the horn, where one float can no longer be submerged and the other float has a correspondingly increased buoyancy range.

and Figures 2 and 2 show a ship with only two side buoys 3, 4. This condition is not necessary.

In the drawing it is shown, by way of example, that the center float 2 is connected posteriorly to the two lateral floats 3, 4 and the front part to the two lateral floats 3a, 4a, the distance between which is preferably but not necessarily different from the distance between the lateral floats 3, 4.

By way of example, Figures 1 and 2 show a vessel having a central hull 2 of approximately 100 m overall length and about 95 m long along the waterline.

As noted above, in this case the width of the central body along the waterline at the midel-boom level should be 8 m, the axis of the side bodies x 15 m from the axis X of the center body, and the rectangular section R1 is substantially rectangular. 30 meters long.

The height of the lateral buoys would in this case be about 5 m at a point of substantially uniform cross-section.

As shown in Figure 2, it is useful if the side floats have lateral torsion stabilizers 24, 25, preferably located on the inner side of the floats.

In part, because the design of the invention gives the ship a torque that is dependent on the angle of the horn and is clearly smaller than that of all other multi-hull vessels, the stabilizers can be low surface and thus low resistance to forward movement. Because stabilizers can be located on the inside surfaces of lateral buoys, there is no need to include them when approaching a berth or in other circumstances, which reduces their cost.

In addition, Figures 1 and 2 show that at least one longitudinal torsion stabilizer 27 can be mounted underneath a central body, preferably at its front. The stabilizer 27 can be of any active type, i.e. a movable keel controlled or regulated by longitudinal torsion movements or of a passive type, i.e. fixed keel. This stabilizer can be connected to the holding plates as will be shown below.

Another embodiment is shown in Figures 9 and 10, where the central float 2 is in the form of a thin hull with a high length to width ratio (LB), the top of the hull being fixed on one side to the underside of platform 1 or other fasteners and on the other , 4.

Preferably, the central buoy 2 and the side buoys are connected by bounding arches 6 and 7 and on the other hand each buoy is connected to the platform by means of arch elements 8 and 9.

It follows that the side buoys have a continuously increasing buoyancy up to platform 1.

Each side float has a thin wall 10 with a substantially cylindrical body 11 having a circular or elliptical section at its lower end, as shown in Figure 10.

If the bottom buoys have casings 11 at the bottom, it is desirable that their axes 11a (Fig. 9) are at the same level as the center buoy keel line 12.

The measures above and the location of the side buoys are chosen to provide the ship with the transverse stability necessary but optimal for normal navigation conditions, i.e., the wave tops not reaching the tops of the arches 6, 7 and the arch members 8, if any.

The arrangement shown above is such that the center float can have waterlines that are very good and extended and suitable for high speeds of movement, and high altitudes, such as 5 to 10 meters lateral buoys per 100 meters of boat length, are always properly submerged, as a result, the vessel becomes less sensitive to the tipping effect. In addition, the small width of the side buoys, preferably about 1 m for a ship length of about 100 meters, is such that the side buoys only generate small waves, which facilitates the propulsion of the ship.

the figure shows the lateral buoys as small, 15 in width, which is practically constant over a greater height.

In this way, the hydrostatic return they form during the transverse tilt of the vessel is not too great, which makes the vessel comfortable for lateral tipping.

Preferably, as shown in the drawings, and partly in Figure 9, the walls 10 are retracted back into the housing 11 to form the capsule 14.

the foreman 13 would be in relation to the foreman,

If the width of the side buoys is about 1 meter, the buoys 11 are about 2-3 meters wide, when they are fully submerged, they form cushioning elements with respect to the lateral torsion, longitudinal torsion and jumping movements. The large length of the center float 2 and the side floats 3, 4 also make up the anti-drift surfaces, which are quite effective and, if necessary, form the ship's sailing motion.

Figure 3 shows floats 3, 4 of constant width. In practice, the width may vary.

io

The wall of each side float is shown as one detail. If necessary, the wall may be partially perforated or made of successive brackets.

The forward movement of the vessel is essentially mechanical (for example, propeller or water jets), although sailing motion can also be easily accomplished, since it is possible to achieve transverse stability by appropriately selecting the distance between the center float and each side float, which , may have a ballast to maintain the lateral ballast stable, towards the crane to compensate one side.

The basic construction according to the invention consists, as shown in Fig. 11, of articulating movement of the side buoys 3, 4 around the longitudinal axes 28, 29 and adjusting the position of the buoys by means of force cylinders 30, 31. According to the variant of Figure 12, the side floats have telescopic parts 3, 4 controlled by force cylinders 32, 33.

In addition to the above and in the embodiment of the present invention, in addition to the stabilizer 27, lateral and central buoys may be provided with bearing planes 34, which may or may not be supported by a stable, dynamic lifting force to partially unload the ship. and the formation of lateral and longitudinal torsion stabilizers by adjusting the proportional load distribution of the vessel. In addition, flexible skirts may be placed between the center float and the side buoy walls to form air inlet tunnels to form lift and cushion pads.

In view of the above and the basic construction of the invention, the platform 1 forms a housing for holding loads. In some cases, the platform may be replaced by other means, such as brackets 17 (Figure 17). The brackets 17, 18 may be independent, consistently spaced or in continuous strip.

application interconnection 18 (12 to form a crossbar

DEFINITION OF INVENTION

Claims (17)

DEFINITION OF INVENTION 1. Multi-hull, at leveling, any ship with a limited transverse and reduced forward movement resistance, having a center buoy (2) connected to at least two lateral buoys (3,4), without any horizontal section forming an area at least 6% of the distance between the axis of the floats (x) and the axis of the vessel (X) above or below any navigational waterline (F) of that vessel, the horizontal cross-sections of the side buoys (3,4,3a, 4a) being such that for floats, the sum of the product of the horizontal cross-section of each float, expressed in square meters, of its square distance between its axis (x) and its axis (X) expressed in meters does not exceed 80% of its weight in metric tonnes the ship's center of gravity (G) in meters; in that at least one side float on each side of the center float is partially submerged, with zero center float and any navigable waterline having at least 1 and a length to width ratio of at least 8. amount of vessel (B) and speed; and the draft ratio, A ship according to claim 1, characterized in that there are at least two side floats (3,4,3a, 4a) with a displacement of at most 20% of the total displacement of the vessel. Ship according to one of Claims 1 to 2, characterized in that the side buoys (3,4,3a, 4a) have a small buoyancy surface which is always less than 15% of the total buoyancy surface of the ship. A ship according to one of claims 1 to 3, characterized in that the length of the lateral floats is at most 40% of the length of the central float along the waterline. Vessel according to one of Claims 1 to 4, characterized in that the lateral buoys have a horizontal cross section that is substantially constant over a greater part of their height. 6. A ship according to one of claims 1 to 5, characterized in that the lateral buoys (3,4) have a horizontal sectional shape which is close to a rectangle or is egg-shaped or wing-shaped or any other shape adapted for hydrodynamics. 7. A ship according to one of claims 1 to 6, characterized in that the lateral buoys have a portion (R _x ) which has a substantially rectangular projection on the horizontal and which transitions into a bow (20) passing through a true or oblique phase (21). ) extending towards the bow of the vessel. 8. A ship according to one of claims 1 to 6, characterized in that the projection of the side floats to the horizontal is rectangular. 9. A ship according to one of claims 1 to 6, characterized in that the side buoys have a trapezoidal (T) shaped portion connected to the sloping nose (22). Ship according to one of Claims 1 to 9, characterized in that each lateral buoy has a hull (11) substantially cylindrical or elliptical in its lower part. 11. A ship according to claim 10, characterized in that the hull (11) of the side buoys protrudes relative to the hull (13) of said buoys, forming a capsule (14). 12. A ship according to claim 1, characterized in that the lateral floats are articulated and their displacement about the axes (28,29) is controlled by the force cylinders (16). 13. A ship according to claim 1, characterized in that the lateral buoys have telescopic parts (3, 4, 44) adjustable by the cylinders (32, 33). 14. A ship according to claim 1, characterized in that the floats have stabilizing and supporting surfaces (27,34). 15. A ship according to claim 1, characterized in that the side floats have ballasts. 16. A ship according to claim 1, characterized in that the lateral torsion stabilizers (24,25) are placed on the inner surface of the lateral floats. 17. A ship according to claim 1, characterized in that for a ship of about 100 m overall length, the center float is at a waterline level of about 95 meters, with a mid beam at 8 meters, a distance between the center float axis (X) and the lateral the float axis (x) is 15 m, and the length of the side floats is 10-30 m, while they are about 1 m wide and about 5 m high and have a substantially rectangular cross-section.