RU2536568C1 - Eyes of ship hull with higher icebreaking capability - Google Patents

Abstract

FIELD: transportation.

SUBSTANCE: invention relates to design of hull lines of a ship hull with higher icebreaking capability having a stem with a bulb. Eyes of a ship hull are proposed, having a bottom in the area of a midship frame with low or zero deadrise and boards close to vertical ones, comprising a bulb having in its upper part a straight or slightly bent rib, formed in the diametral plane during connection of the right and left surfaces of the bulb at the spatial angle of 30-150°, having an inclination forward to 30° to the plane of the waterline and crossing planes (levels) of the highest and lowest positions of the rated waterline of the ship in the head for different versions of its load. The upper surface of the bulb is made with gradual rise from its front part to the area of coupling with main hull lines, the length of the body part of the bulb in the longitudinal direction makes 4-5 theoretical spaces. Cross sections of the bulb vary slightly along the width from 1 to 3 of the theoretical frame. Coupling of the eyes with the bulb lines is made to form concavity of buttocks, stretching at the angle downwards from the start of coupling on the stem to the area of approximately 3-4 of the theoretical frame.

EFFECT: increased icebreaking capability of a ship and speed of its movement.

5 cl, 3 dwg

Description

The invention relates to the hull of a vessel, more specifically to the bow of a vessel with increased ice penetration, having a stem with a bulb.

Ship hulls are known for overcoming ice-covered waters that destroy ice with the help of a nasal bulb breaking ice with pressure from the bottom up.

US Pat. No. 5,936,642, publication November 16, 1897, describes the design of an icebreaker with a bulb in the bow for breaking ice. Bulb is located below the structural waterline; in vertical sections perpendicular to the diametrical plane of the vessel, it is essentially tear-shaped with an expansion in the lower part of the bulb.

In the application KR 20080107070, publication 10.12.2008, IPC B63B 35/08, describes the bow of an icebreaking vessel with a bow bulb for breaking ice. To improve the process of ice destruction, the shape of the bulb is specified. The angle between the main plane of the vessel and the upper surface of the bulb lies in the range of angles 15-20 °. The angle of sharpening of the nasal profile is: minimum 30 degrees and maximum 65 degrees.

Vessels of various purposes, which are not icebreakers, but can independently overcome ice-covered waters, have also gained distribution. A variety of requirements are imposed on such vessels, including the requirements for seaworthiness, both when crossing ice areas and when sailing in clean water.

In the patent US 3521590, publication 07/21/1970, IPC B63B 35/08, describes the design of the vessel. The nose of the icebreaker contains a symmetrical bulb located below the waterline. In cross section, the bulb is wider than the height. The bulbous bulb is equipped with a blade so that the destruction of ice occurs more efficiently. The contours of the vessel provide for the lifting of broken ice on the surface of the bulb and laying it on ice on the sides of the punched channel.

Closest to the claimed designation is the bow of the transport icebreaking vessel according to patent RU 2217348, adopted as a prototype, publication November 27, 2003, IPC B63B 35/08. The aim of the invention is the creation of a vessel that operates efficiently when moving both in clean water and in ice conditions. This goal is ensured mainly by the shape of the contours in the stern of the vessel. However, to reduce wave resistance, the vessel in the bow has a bulbous formation. In addition, the “shape of the contours of the nasal extremity with pointed waterlines provides the ability to maneuver the vessel back and forth in broken ice. In addition, due to the proposed shape of the nasal tip, the ice load at the place where the bulb and the body are in conjunction in the vicinity of the stem are slightly reduced. ”

The disadvantages of this form of the nasal tip can be attributed to the fact that the bulbous formation in combination with the contours of the nasal tip provides only a decrease in wave resistance in clean water, but does not provide an increase in the speed of the vessel when passing through an area covered with ice.

The technical result achieved in this invention is to increase the ice penetration of the vessel and increase the speed of movement both in ice conditions and in clean water.

The nasal tip of the hull of the vessel with increased ice penetration, having a bottom with a low or zero deadlift in the midship frame region and sides close to vertical, characterized in that the bow tip has a bulb having in its upper part a straight or slightly curved rib formed in the diametrical plane when connecting the right and left surfaces of the bulb at a spatial angle of 30-150 °, having a forward slope of up to 30 ° to the waterline plane and intersecting the planes (levels) of the uppermost and lowest position of the calculated waterline of the vessel in the bow for different options for loading it. In addition, the upper surface of the bulb is made with a gradual rise from its frontal part to the place of interfacing with the contours of the main body, the length of the body of the bulb in the longitudinal direction is 4-5 theoretical spacings, while the cross sections of the bulb vary little in width from 1 to 3 theoretical frame. The pairing of the nasal extremity with the contours of the bulb is made with the formation of concavity of buttocks, going at an angle downward from the beginning of pairing on the stem to the area of about 3-4 theoretical frames.

Ice penetration of the vessel is ensured by the presence of a bulb, which is designed for breaking ice, its location and shape. Bulb is located in such a way that it will break the ice at any loading of the vessel. Ice breaking is facilitated by the presence of a rib formed in the diametrical plane, which allows breaking ice in the region of the diametrical plane of the vessel. Broken ice floes, due to the shape and direction of conjugation of the bulb’s nasal tip, are first partially pushed up together with the retaining wave, turned and then directed downward, under the ice edge, and pushed out under the ice of the formed channel, due to the fact that the vessel in the mid-frame area has side, close to vertical, and the bottom with low or zero pitching. Due to this shape of the bulb, together with the peculiarities of the conjugation form of the bulb and the bow tip, as well as the shape of the transition from the bow tip to the ship’s hull itself, the broken ice is effectively removed under the ice edge of the channel, thereby facilitating the operation of the ship’s propellers, reducing the resistance to the hull’s movement and thereby providing increased speed in the ice. In particular, “mashing” of ice between the ship’s hull and the edge of the channel does not occur, which usually leads to a decrease in the speed of the ship. An additional result is the presence of a channel with clean water behind the vessel, which provides easier navigation of vessels following.

The proposed hull form also provides an increase in the speed of the vessel and in clean water. The shape of the bulb provides for the forced formation of streamlines flowing around the body of the liquid, thereby ensuring an optimal distribution of the water flow throughout the body, reducing resistance, and, as a result, contributes to an increase in speed. In this case, the necessary flow formation is also due to the shape and direction of conjugation of the nose of the bulb: the flow is also directed downward, under the hull of the vessel, which provides less loss of wave formation during vessel movement.

Thus, all the features of the invention, acting in close interconnection, provide the result: increased speed of the vessel in clean water and in ice, combined with increased ice permeability.

In the particular case of the bow of the vessel, its sides are made with a collapse from zero to almost 9 theoretical frames.

In addition, the lower part of the bulb is a continuation of the bottom of the body and has a small transverse curvature.

The width of the bulb can be up to 0.5 of the width of the body.

The concavity of the buttocks in the area of coupling of the contours of the nasal extremity with the contours of the bulb is directed downward in the range of angles from 15 ° to 21 ° relative to the plane of the waterline, which provides the best conditions when moving in ice and in clear water.

The invention is illustrated by drawings.

Figure 1 presents a theoretical drawing of the bow of the vessel, where

a) side view; b) horizontal projection; c) transverse projection.

Figure 2 presents a drawing of a part of the nasal extremity with projections: a) side view and c) transverse projection.

Figure 3 presents a theoretical drawing of a vessel made using the invention in three projections.

The nasal tip 1 of the vessel (FIG. 1, FIG. 2) contains a bulb 2 having in its upper part a straight or slightly curved rib 3 formed in the diametrical plane when the right and left surfaces of the bulb 2 are connected at a spatial angle α = 30-150 ° (Figure 2). Rib 3 (Figure 2) has a forward inclination at an angle β up to 30 ° to the plane of the waterline (KVL) and intersecting the planes of the uppermost and lowest positions of the calculated waterline of the vessel in the bow for different loading options. The upper surface of the bulb 2 is made with a gradual rise from its frontal part to the place of interfacing with the contours of the main body. The length of the body of the bulb 2 in the longitudinal direction is 4-5 spacings, while the cross sections of the bulb vary little in width from 1 to 3 frames. The pairing of the nasal tip with the contours of the bulb 2 is made with the formation of concavity 4 buttocks, going at an angle γ down from the beginning of the pair on the stem to the area of about 3-4 frames in the range of angles γ from 15 ° to 21 ° (Figure 2) relative to the plane of the waterline. The best result is achieved in the range of angles γ from 16 ° to 17 °. This concavity 4 provides the best conditions when moving in ice and in clear water. The nasal tip 1 also has a bottom 5 in the midship-frame region with low or zero deadrise and sides close to vertical. Succulent 6 in the mid-frame area is rounded. The sides of the bow 1 for the best seaworthiness of the vessel are made with a collapse from zero to almost 9 frames. The lower part of the bulb 2 is a continuation of the bottom 5 of the housing and has a small transverse curvature. The width of the bulb 1 can be up to 0.5 of the width of the housing.

The proposed shape of the nasal tip is able to provide good ice patency due to the bulb 1, which breaks the ice with a thickness of at least 0.6 meters, ensures the passage of the vessel through the ice, including hummocked ice at a fairly high speed. All this is provided by the shape and location of the bulb, the form of mating the bulb with the main body and the shape of the nasal tip. When passing through the water area with ice cover, bulb 2 with rib 3 breaks the ice cover. Due to the shape of the bulb 2, the shape of the stem 7 and the shape of the concavity 4 of the buttocks in the places where the bulb 2 meets the contours of the hull, conditions are created for the destruction of ice and the displacement of ice under the edges of the channel formed when the vessel moves.

When moving in clean water, the retaining wave directs part of the flow down under the body, which helps to reduce resistance, including due to less wave formation. This creates the conditions for increasing the ice penetration of the vessel and increasing the speed of movement both in ice conditions and in clean water.

Figure 3 presents an example of the use of the shape and size of the bow 1 in the design of the vessel. The aft end of the vessel is designed in such a way as to provide reverse movement of the vessel in the ice cover, which is achieved by the contours and the position of the propeller-steering group.

In the process of testing, the model of this vessel showed high speed both in clean water and in a channel with shallow ice. Tests also show that the vessel will cross a flat annual ice 0.6 meters thick without stopping at a speed of about 6 knots.

Claims (5)

1. The nasal tip of the hull of the vessel with increased ice penetration, having a bottom with a low or zero deadlift in the midship frame region and sides that are close to vertical, characterized in that the bow tip has a bulb having in its upper part a straight or slightly curved rib formed in the diameter plane when connecting the right and left surfaces of the bulb at a spatial angle of 30-150 °, having a forward slope of up to 30 ° to the waterline plane and intersecting the planes of the highest and lowest positions th design waterline of the vessel in the bow for different options for loading it; in addition, the upper surface of the bulb is made with a gradual rise from its frontal part to the interface with the contours of the main body, the length of the body of the bulb in the longitudinal direction is 4-5 theoretical spacings, while the cross-sections of the bulb vary little in width from 1 to 3 theoretical the frame, the pairing of the nasal extremity with the contours of the bulb is made with the formation of concavity buttocks, going at an angle downward from the beginning of pairing on the stem to the area of about 3-4 theoretical frames. 2. The nasal tip of the hull according to claim 1, characterized in that the sides of the vessel are made with a collapse from zero to almost 9 theoretical frames. 3. The nasal tip of the body according to claim 1, characterized in that the lower part of the bulb is a continuation of the bottom of the body and has a small transverse curvature. 4. The nasal tip of the body according to claim 1, characterized in that the bulb width is up to 0.5 of the body width. 5. The nasal tip of the hull according to claim 1, characterized in that the said concavity of the buttocks in the area of pairing of the contours of the nasal tip with the contours of the bulb is directed downward in the angle range from 15 ° to 21 ° relative to the plane of the waterline.

Images