RU2588564C1 - Device for breaking down ice cover - Google Patents

Abstract

FIELD: shipbuilding.

SUBSTANCE: invention relates to underwater vessels which break down ice using a resonance method. Device for ice breaking consists of a submarine vessel, capable of moving under ice cover and excite therein resonance flexural-gravity waves. Vessel has in water-flow channels between its strong and light two impellers, cross-sections of which are located perpendicular to longitudinal axis of vessel, they are located one after another and have in top parts open sections. Impeller can rotate in opposite directions, and blade impellers at end of open channel sections-deviate, that is, be held down to inner surface of impellers, for a time equal to time of approach to closed sections of next blades, and then come back into initial position, impellers also have possibility of periodically with frequency of resonance flexural-gravity waves start and stop rotation for a time equal to half-period of said waves.

EFFECT: higher efficiency of ice breaking.

1 cl, 3 dwg

Description

The invention relates to the field of shipbuilding, in particular to submarines destroying ice cover by the resonance method, i.e. by excitation in the ice sheet of resonant flexural-gravitational waves (IGW) (1. Kozin VM Resonance method of destruction of the ice sheet. Inventions and experiments. - Moscow: Publishing House "Academy of Natural Sciences". 2007. - 355 p. ISBN 978- 5-91327-017-7).

A technical solution is known (2. RU2240252 C2, 02.28.2002), in which it is proposed to destroy the ice cover by an underwater vessel by creating from the rotation of the impeller located in the upper part of the vessel's hull an area of increased pressure under the arising top of the IHV.

The disadvantages of this solution are: the presence on the hull of the protruding part in the form of an impeller, which increases the resistance of water and, consequently, reduces its speed; the cumbersome design of the impeller beyond the dimensions of the housing; low working capacity of the solution due to the hydrodynamic imperfection of its implementation (the absence of the targeted, i.e. focused, effect of the generated hydrodynamic forces on the top of the IGW) and, accordingly, the insufficient height of the excited IGV.

The essence of the invention consists in the development of a device installed in the hull of the vessel and increasing the height of the IHV, excited when the vessel moves under ice cover.

The technical result obtained by carrying out the invention is to increase the thickness of destructible ice.

The essential features characterizing the invention.

Restrictive: a device for destroying the ice cover, consisting of an underwater vessel, capable of driving resonant bending-gravitational waves in it under the ice cover and creating, using a rotating impeller located in the upper part of the ship's hull, an area of increased pressure under the ice cover at the location peaks of a bending gravitational wave.

Distinctive: on the vessel, two impellers are installed between the strong and light hulls of the water-flowing channels, the cross sections of which are perpendicular to the longitudinal axis of the vessel, they are located one after the other and have open sections in the upper parts, the impellers can rotate in opposite directions, and impeller blades at the moment of completion of passage of open sections of channels by them - deviate, i.e. press against the inner surface of the impellers for a time equal to the approach time to the closed areas of the next blades, and then return to their original position, the impellers also have the ability to periodically start and stop their rotation with a frequency of resonant flexural-gravitational waves for a time equal to the half-period of these waves , the blades are bent in the directions opposite to the directions of rotation of the impellers.

It is well known that during the rotational motion of a medium, centrifugal forces will inevitably act on its mass. This obvious pattern can be used to increase the efficiency of ice cover destruction by the resonance method using the proposed device. To do this, these forces should be directed below the top of the excited IGW, which will increase the hydrodynamic pressure in this area, i.e. increase the height of the IHV.

It is known (3. Loytsyansky LG, Mechanics of liquid and gas. - M.: Drofa. 2003. - 842 p.) That during the interaction of fluid flows with different velocities, a boundary layer arises at the interface, within the thickness of which Due to the viscosity of the fluid, the velocities in the flows change sharply in the directions transverse to them. Thus, with the oncoming movement of two fluid flows with the same speed and viscosity, which will be created by the proposed device, at their interface, they will mutual inhibition with intense vortex formation. Then, in accordance with Bernoulli’s law, the pressure at this boundary will increase and, as a result, a peculiar hydrodynamic barrier (hydrodynamic resistance) will arise that prevents the incoming external flow from flowing through it (in our case, when considering for a better understanding of the reversed motion (see [3])) , i.e. when the vessel is considered motionless, and the water and ice cover seem to be approaching it, the speed of the external flow will be equal to the speed of the vessel, which will increase the pressure in front of it. In addition, a swirling liquid region will appear on the path of the external flow at the device’s location between the ship’s hull and the lower surface of the ice sheet, which will increase the degree of turbulence of not only the boundary layer that occurs on the surface of the vessel itself, but will also lead to turbulence of the entire external flow between his hull and ice. The viscosity of the vessel will increase, which, in turn, will increase the pressure in this area (see [3]).

It is also known (4. D.E. Heysin. Dynamics of ice cover. - L .: Gidrometeoizdat, 1967. - 218 p.) That the application of a periodic dynamic load to the ice cover with a frequency equal to the frequency of resonant IGW significantly increases the deformation of the ice cover in comparison with the same intensity load, but applied stationary. This is explained by the fact that under such influences resonant IGWs arise. Thus, if under the apex of the IGW arising from the translational movement of the submarine (the main resonant IGV), a period of increased pressure is created periodically with the frequency of the resonant IGV, this will lead to the excitation of additional resonant IGV in the ice sheet.

Obviously, in order to achieve the maximum periodic increase in the amplitude of the total IHV, it is necessary that the exposure time of the forces exciting additional IHV is equal to half the period T of the main resonant IHV, the value of which can be determined from the dependence [4]

where D is the cylindrical stiffness of the ice plate; ρ _l is the density of ice; h is the thickness of the ice cover; g is the acceleration of gravity.

In this case, when the ice moves up from the additional IGWs that have arisen, the forces that excite them will also be directed up, and when the ice moves down, these forces disappear. Thus, the most effective kind of additional build-up of ice cover to the main IGW will arise.

The invention is as follows.

In the ship’s hull, at the most probable location of the IGV peak, two water-flowing channels with open sections in the upper parts are made. Impellers are installed in the channels, which are configured to rotate in opposite directions and equipped with vanes bent in directions opposite to the directions of rotation of the impellers. This shape of the blades, as well as the shape of the blades of the impellers of centrifugal pumps, increases their efficiency. In our case, it creates, at given energy inputs, the maximum centrifugal forces arising from the ejection of impellers through the open sections of water-flowing channels of water masses. The dimensions of the channels and impellers do not exceed the dimensions of the vessel at their location, which, unlike the analogue, does not lead to the appearance of additional resistance in the form of the resistance of its protruding parts. The vertical arrangement of the walls of the channels will provide a strict direction (focused effect) of the ejected water flows under the top of the IHV. In addition to increasing the pressure under the summit of the IGW due to the centrifugal forces created by the device and the swirling liquid region, its operation due to the proximity of the water flow channels (one after another) will result in hydrodynamic interaction of the water flows excited by the impellers. Rotation of the impellers in opposite directions not only eliminates the occurrence of heeling moment, worsening the lateral stability of the vessel, but also leads to the appearance of a hydrodynamic barrier perpendicular to the direction of movement of the vessel, increasing the operability of the proposed device. To ensure that the working volume of the impellers can be filled with outboard water after the masses of water are ejected through open sections of the water-flowing channels due to the centrifugal forces of the blade, they are rejected at the moment they pass the open sections of the channels, i.e. pressed against the inner surface of the impellers. For deflected blades due to water displacement, areas of reduced pressure will appear [3], where outboard water will rush, thereby ensuring the occupancy of these parts of the working volumes of the impellers. After the expiration of the time equal to the approach time to the closed sections of the channels of the next blades, they return to their original position. As a result, the entire working volume of the impellers, except for the open sections of the channels, will be filled with sea water. The operation of the device will provide a higher pressure increase under the top of the IHV than the analogue. If this turns out to be insufficient to destroy the ice cover of a given thickness, then the impellers begin to periodically rotate and stop for a time equal to the half-period of these waves with the frequency of resonant IGWs. As a result, under the apex of IGW arising from the translational movement of the vessel (the main resonant IGV), a period of increased pressure will periodically arise with the frequency of resonant IGV, which will lead to the excitation of additional resonant IGV in the ice sheet. Due to interference of the IGW, the height of the total waves will increase, which will achieve the claimed technical result.

The invention is illustrated by drawings, where in FIG. 1 shows a side view of the device; in FIG. 2 and 3 are cross-sections along Α-A and BB in FIG. one.

In the hull of the vessel 1 there are two water-flowing channels 2 with open sections 3 (Fig. 1-3). In the channels 2, impellers 4 are installed, equipped with blades 5, which are made with the ability to rotate in opposite directions (Fig. 2, 3). If, when the vessel 1 moves with a resonant speed u _p under the ice sheet 6, the height of the excited IGV 7 is insufficient to destroy the ice sheet, then the impellers begin to rotate with angular velocities ± ω, respectively, which will lead to the release of 2 masses of water through open sections 3 of the flow channels 8 and 9 (Fig. 2, 3), which will have both radial components 10 (due to centrifugal forces) and opposite circumferential velocity components 11 (due to the twisting of water in the corresponding channels 2 (Fig. 2, 3)) . The water flow (components 10) arising due to centrifugal forces will lead to an increase in pressure under the summit of the IGW 7. The circumferential components 11 will cause the appearance of a hydrodynamic barrier 12 and the turbulence of the external flow 13. The vanes 14 at the moment they pass through the open sections of 3 channels 2 are rejected, i.e. e. pressed against the inner surface of the impellers 4, which will lead to the appearance of areas of reduced pressure 15 and, consequently, flows of overboard water 16 (Fig. 2, 3) filling the area 15. As a result of the operation of the device, an increase in height from IGV 7 to IGV 17 will occur. If this is not enough to destroy the ice cover of a given thickness, then the impellers 4 begin to periodically rotate and stop with the frequency of the resonant IGV for a time equal to the half-period of the resonant IGV. This will lead to the excitation of an additional system of resonant IHV 18. The superposition of the wave system 17 on the system 18 will cause an increase in the amplitudes of the IHV to the IHV 19 (Fig. 1).

Claims (2)

1. Device for breaking the ice cover, consisting of an underwater vessel, capable of driving resonant bending-gravitational waves in it under the ice cover and creating with the help of a rotating impeller located in the upper part of the ship's hull an area of increased pressure under the ice cover at the location the tops of the bending-gravitational wave, characterized in that on the vessel two impellers are installed between the strong and light hulls of the water-flowing channels, the cross sections of which X arranged perpendicularly to the longitudinal axis of the vessel, they are arranged one behind the other and have in the upper parts of the open areas, the impeller adapted to rotate in opposite directions, and the impeller blade at the time of closure of the passage portions open channels - deflected, i.e. press against the inner surface of the impellers for a time equal to the approach time to the closed areas of the next blades, and then return to their original position, the impellers also have the ability to periodically start and stop their rotation with a frequency of resonant flexural-gravitational waves for a time equal to the half-period of these waves . 2. The device according to p. 1, characterized in that the blades are bent in directions opposite to the directions of rotation of the impellers.

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