RU2495781C1 - Ship tunnel-type aft - Google Patents

Abstract

FIELD: transport.

SUBSTANCE: invention relates to ship building, particularly, to design of ship aft with water-jet propulsors. Ship tunnel-type aft has clear-water hull and underwater hull with bottom with at least one lengthwise cross-section arc-like channel extending along the entire ship hull under design waterline. Underwater hull cross-section profile along design waterline features maximum width at aft area. Bottom surface between the walls of boards and channel are shaped to half-cones with vertices at ship bow and vertices at ship aft. Water-jet propulsors are built in said half-cones at underwater ship aft. Extra water-jet propulsor is built in ship aft lengthwise channel top part.

EFFECT: better propulsive properties and navigability.

3 cl, 5 dwg

Description

The invention relates to the field of shipbuilding and for the construction of the aft end of the vessel having water-jet propulsion.

Known aft end of a tunnel-type vessel (patent RU No. 2302971, class B63B 1/00, 1/40, 2006) comprising a surface hull and an underwater hull having a bottom with at least one longitudinal arcuate cross-sectional channel extending along the entire the hull of the vessel and located below the structural waterline, and the sectional profile of the underwater hull along the constructive waterline has a maximum width in the stern area, and the bottom surfaces side-by-side between the walls of the sides and the channel are made in the form of semi-cones with vertices in the nose water and bases in the aft end of the hull, while in the aft end of the underwater hull, water-jet propulsors are built into its semiconical formations below the structural waterline. This device is adopted as a prototype.

As follows from the description of the prototype device, at least one longitudinal arch-shaped channel in cross section is made in the bottom below the structural waterline. Due to the proposed geometry of the shape of the underwater hull, it is possible to achieve a minimum wave resistance.

In another embodiment, when two longitudinal channels are carried out in the bottom of the vessel symmetrically to the ship’s diametric plane, it will further improve the seaworthiness of the vessel, in particular, increase the controllability of the vessel and reduce the side rolling on waves due to the diversity of the underwater hulls.

The installation in the aft end of the underwater hull below the waterline of the jet propulsion with fixed nozzles embedded directly in the semiconical formations of the underwater hull will make it possible to reduce the thickness of the boundary layer in this area during the operation of the jet propulsion in the aft zone of the longitudinal channel and, therefore, reduce the likelihood of backwater channel, which will reduce the resistance of water to the movement of the vessel and will lead to a significant increase in the propulsive qualities of the vessel.

A technical solution is also known (US patent No. 4823722, class B63G 8/22, 1989), when the propulsion device is located in the middle behind the longitudinal channel to improve the effective intake of the propulsion device. By means of water intake by the mover, an increase in the speed of water flow through the longitudinal channel and control of the boundary layer on the surface of the underwater hull of the vessel in the longitudinal channel are carried out.

The aim of the invention is to increase the propulsive and seaworthiness of the vessel due to the additional utilization of the boundary layer in the region of the upper part of the longitudinal channel through the installation in this area of an additional jet propulsion.

The goal is achieved in that in the aft end of a tunnel-type vessel containing a surface hull and an underwater hull having a bottom with at least one longitudinal arcuate cross-sectional channel extending along the entire hull of the vessel and located below the structural waterline, and the sectional profile of the underwater hull along the structural waterline has a maximum width in the stern area, and the bottom surfaces flush between the walls of the sides and the channel are made in the form of semi-cones with vertices in the bow and are based s in the aft ends of the housing, the aft end of the underwater housing in its semi-conical formation integrated water jets, according to the proposed technical solution in the upper part of the longitudinal channel in the rear end of the jet propulsion unit is integrated.

In addition, in each water-jet propulsion device built into the semiconical formations below the structural waterline, water intake openings are located located in the walls of the longitudinal channel.

It is advisable to install an additional water jet propulsion above the upper wall of the longitudinal channel with a water intake hole made in the upper wall of the longitudinal channel.

The invention is illustrated by drawings, where:

figure 1 is a view of the stern on the hull with an additional jet propulsion device located below the upper wall of the longitudinal channel, and jet propulsion devices installed in semiconical formations with water inlets in the longitudinal channel;

figure 2 - section aa of the aft end of the vessel of the tunnel type in figure 1;

figure 3 - view of the stern on the hull with an additional water jet propulsion located above the upper wall of the longitudinal channel, with a water intake hole made in the upper wall of the longitudinal channel, and water jet engines installed in the semiconical formations, with water intake holes made in the walls of the longitudinal channel ;

figure 4 - section bb of the aft end of the vessel of the tunnel type in figure 3;

5 is a view of the stern on the hull with two longitudinal channels. The hull of the vessel contains a surface hull 1 above the structural water line 2 and the underwater hull 3 below the structural water line 2. The surface hull 1 can be of any shape depending on the purpose of the vessel. The underwater housing 3 has a bottom 4 with at least one longitudinal channel 5 and curved sides 6, converging to the nose. The longitudinal channel 5 is located below the structural water line 2 and is made arch-shaped in cross section. The cross-sectional profile of the underwater hull 3 along the constructive waterline 2 has a maximum width in the stern area. The surfaces of the bottom 4 flush between the walls of the sides 6 and channel 5 are made in the form of semi-cones with peaks in the bow and bases in the aft ends of the underwater hull 3. At the aft end of the underwater hull 3, water-jet propulsors 7 with water inlets 8 made in the longitudinal walls are built into the semiconical formations channel 5. In the upper part of each longitudinal channel 5 in the aft end there is an additional water-jet propulsion 9 with a water intake hole 10. As options: additional water-jet propulsion A body 9 with a water inlet 10 may be located below the upper wall of the longitudinal channel 5 (Figs. 1 and 2) and higher than the upper wall of the longitudinal channel 5 with a water inlet 10 made in the upper wall of the longitudinal channel 5 (Figs. 3 and 4). Figure 5 shows a variant with two longitudinal channels 5, in which water-jet propulsion devices 7 are integrated in the semiconical formations, and additional water-jet propulsion devices 9 are integrated in the upper part of the aft end of each longitudinal channel 5.

When the vessel moves on its entire surface below the structural waterline 2, a boundary layer is formed. Moreover, on the walls of the longitudinal channel 5, the value of this boundary layer due to interference will be greater than along the outer sides 6 and bottom 4. The vessel, when moving, carries with it additional masses of water in the boundary layer, the movement of which requires additional energy.

An additional jet propulsion device 9, installed in the region of the upper part of the longitudinal channel 5, utilizes the boundary layer on the upper surface of the longitudinal channel 5, which will also increase the propulsive qualities of the vessel.

Water jet propulsion 7 with water intake holes 8 made directly in the walls of the longitudinal channel 5, will allow more efficient to utilize the boundary layer in the longitudinal channel 5. In this case, the longitudinal axis of the water intake holes 8 for the water jet propulsion 7 can be made not lower than the axis of the impeller of the water jet propulsion 7, which will allow you to remove the loss of water rise, compared with conventional water-jet propulsors with bottom water intake, which will increase the efficiency of water-jet propulsion 7, and therefore, increase propulsive qualities vessel.

At the same time, water jet propulsion 7 with water inlet holes 8 in the longitudinal channel 5 and an additional water jet propulsion 9 with water intake hole 10 in the upper part of the longitudinal channel 5 will allow to utilize the boundary layer due to suction of the water flow in the longitudinal channel 5, and therefore, the likelihood of an inhibited flow will be reduced water in the longitudinal channel 5, which with a small relative width of the longitudinal channel 5 can lead to an increase in water resistance to the movement of the vessel.

It should be noted that during the movement of a tunnel-type vessel on a wave, the sides 6 and bottom 4 may be partially exposed. When the water intake of the jet propulsion device is located in these areas, air breakthrough may occur, which will sharply reduce its hydrodynamic characteristics and, consequently, lead to a decrease in propulsive qualities vessel. While in the longitudinal channel 5 there will be no excitement. Therefore, the location of the water intake openings 8 and 10 in the longitudinal channel 5 eliminates the possibility of air breakthrough into the water jet propulsion 7 and the additional water jet propulsion 9, and therefore will ensure their reliable operation under various operating conditions of the tunnel type vessel.

When only water-jet propulsion 7 is operating, the installation of an additional water-jet propulsion 9 with a water intake hole 10 above the upper wall of the longitudinal channel 5 with its protruding parts will not create water resistance in the longitudinal channel 5 when the vessel is moving.

The implementation in the bottom 4 of two or more longitudinal channels 5 will improve the seaworthiness of the vessel, in particular, to increase the controllability of the vessel and reduce the side rolling on waves due to the spacing of the bearing parts of the underwater hull 3.

As a result, the proposed options for the aft end of a tunnel-type vessel with water-jet propulsion due to the utilization of the boundary layer in the longitudinal channel will improve the propulsion and seaworthiness of the vessel.

Claims (3)

1. The aft end of the tunnel-type vessel, comprising a surface hull and an underwater hull having a bottom with at least one longitudinal arcuate cross-sectional channel extending along the entire hull of the vessel and located below the structural waterline, the cross-sectional profile of the underwater hull along the structural waterline has a maximum width in the area of the stern, and the bottom surfaces flush between the walls of the sides and the channel are made in the form of semi-cones with peaks in the bow and bases in the stern end tyah body, the aft end of the underwater housing in its semi-conical formation below the design waterline integrated water jets, characterized in that the upper part of the longitudinal bore in the rear end of the jet propulsion unit is integrated. 2. The aft end of the tunnel-type vessel according to claim 1, characterized in that in each water-jet propulsion device built into the semiconical formations below the structural waterline, water inlets are located located in the walls of the longitudinal channel. 3. The aft end of the tunnel-type vessel according to claim 1, characterized in that the additional jet propulsion is built above the upper wall of the longitudinal channel with a water intake hole made in the upper wall of the longitudinal channel.

Images