RU2219090C2 - Method of breaking ice cover - Google Patents

Abstract

FIELD: shipbuilding; submarine vessels breaking ice cover by resonance flexural gravitational waves. SUBSTANCE: proposed method includes exciting resonance flexural gravitational waves in ice when submarine vessel runs at resonance speed and building-up area at increased pressure by means of centripetal forces caused by rotation of impeller and area at reduced pressure by means of centrifugal forces under ice; said impeller is located in area where crests of flexural gravitational waves are located. Centrifugal forces are excited by direct rotation of impeller and centripetal forces are excited by reversing direction of rotation of impeller. Change of direction of rotation of impeller is performed repeatedly at doubled frequency of resonance flexural gravitational waves. Duration of direct and opposite rotation of impeller is equal to half-period of resonance flexural gravitational waves. EFFECT: enhanced efficiency of ice breaking. 2 cl, 1 dwg

Description

 The invention relates to the field of shipbuilding, in particular to submarines sailing in ice conditions and destroying the ice cover in a resonant way when surfacing in solid ice.

The prior art is known from the method of ice cover destruction by resonant flexural-gravitational waves (IGW) excited by an underwater vessel (1. V.M. Kozin, A.V. Onishchuk. Model studies of wave formation in continuous ice cover from the movement of an underwater vessel. -PMTF, Novosibirsk, Nauka Publishing House, 1994, 2, pp. 78-91), in which it is proposed to destroy the ice cover by an underwater vessel by excitation of flexural-gravitational waves when it moves with a resonant speed ν _p , i.e. at the speed at which the amplitude of the excited IGV is maximum.

 It is also known a technical solution (2. RU 2170687 C1, 03/15/2000), in which, to increase the efficiency of ice destruction, it is proposed to create a bending-gravitational rarefaction wave (region of reduced pressure) under the ice cover at the location of the depression (sole) by means of centrifugal forces from rotation impeller located in the upper part of the hull.

 The disadvantage of this method is the insufficient increase in the amplitude of the IGV, i.e., the ice-breaking ability of the vessel, when it moves at a resonant speed.

 The essence of the invention lies in the development of a method of increasing the amplitude of IVG.

 The technical result obtained by carrying out the invention is to increase the efficiency of ice destruction by an underwater vessel.

 The essential features characterizing the invention.

 Restrictive: the ice cover is destroyed by an underwater vessel by exciting resonant IGWs in ice when it moves at a resonant speed and creating an area of reduced pressure under the ice cover at the location of the bend of the gravitational wave by centrifugal forces from the rotation of the impeller located in the upper part of the ship's hull.

 Distinctive: under the ice cover, both a region of reduced pressure is created by centrifugal forces, and a region of increased pressure by centripetal forces from the rotation of the impeller, while centrifugal forces are excited by direct rotation of the impeller, and centripetal forces by a change in the direction of rotation of the impeller to the opposite, with a change in the direction of rotation of the impeller carry out repeatedly and periodically with twice the frequency of resonant flexural-gravitational waves, and the duration of rotation Nij impeller is equal to a half period of the resonant flexural gravitational waves, wherein the impeller blades have a curved shape characteristic for centrifugal pumps blades.

 It is known [1] that the IGV system originates directly above its source (submarine vessel). Therefore, disturbances introduced into the flow in the field of generation of IGW will have a direct impact on the process of their development. Since the first sole of progressive IHV is formed above the hull of the vessel [1], it becomes possible to influence the reaction of the elastic base (water) from deformation of the ice cover within the vessel's length.

 It is also known (3. D.E. Kheisin. Dynamics of ice cover. L .: Gidrometeoizdat, 1967, 218 pp.) 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 resonant IHVs arise under such influences.

где D - цилиндрическая жесткость льда; ρ_л - плотность льда; h - толщина ледяного покрова; g - ускорение силы тяжести.Thus, if under the sole of progressive IHV arising from the progressive movement of the submarine, i.e. main resonant IGVs, to create periodically low and high pressure regions with twice the frequency of resonant IGVs, and to ensure the creation of each of these regions for a time equal to the half-period of resonant IGVs, this will lead to the excitation of an additional system of resonant IGVs in the ice sheet. Moreover, the period of resonant IGW T can be determined by the dependence [3]:

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

 In this case, additional IGVs will be superimposed periodically on the main IGV in the phase, i.e. after time T, the sole of additional resonant IGVs will be superimposed on the sole of the main resonant IGVs. Thus, the most effective kind of additional build-up of ice cover to the main IGW will arise.

 The method is as follows.

Under the ice cover at a given depth, they begin to move the submarine at a speed of ν _p to excite the main resonant IHV. If the amplitude of these waves is insufficient to destroy the ice cover, then they include an impeller pre-installed in the upper part of the hull at the most probable location of the bottom of the wave. As experiments [1] showed, the location of the bottom of the wave is practically independent of the speed of the deepening vessel and the thickness of the ice and is determined only by the geometry of the hull. In this case, the impeller is first rotated in one (forward) direction, and then in the opposite direction. In the forward direction, the additional impeller excites centrifugal forces, i.e. under the base of the main IHV, a rarefaction region will arise, while on the opposite, centripetal, i.e. under the sole of the main IHV, an area of increased pressure will arise. Changing the direction of rotation of the impeller is carried out repeatedly and periodically with twice the frequency of the resonant IHV, and the duration of the direct and opposite rotations is provided for a time equal to the half-period of the resonant IHV, i.e. T / 2. The process of periodically changing the direction of rotation of the impeller continues throughout the entire icebreaking period.

 A periodic change in the direction of rotation of the impeller will cause the appearance of periodic centrifugal and centripetal forces, i.e. to the occurrence under the sole of the main IHV, respectively, of periodically arising areas of low and high pressure. In turn, this will lead to the generation in the sole region of the main resonant IGVs of an additional system of resonant IGVs. Periodic overlapping of additional IGVs in phase on the main IGVs (i.e., after time T the soles of the main and additional IGVs overlap each other) will cause a summation of their amplitudes. As a result, the amplitude of total IHV will increase, which will increase the efficiency of ice destruction.

 The drawing shows a diagram of an embodiment of the invention.

Under the ice cover 1 at a given depth H begin to move the submarine 2 at a speed of ν _p . If the amplitude of the excited main resonant IGW 3 is not sufficient to destroy the ice cover 1, then turn on the impeller 4, pre-installed in the upper part of the hull at the location of the base of the wave 5. In this case, the impeller 4 is first rotated in one direction, and then in the opposite direction. A periodic change in the direction of rotation of the impeller 4 will lead to the periodic appearance of a region of low and high pressures 6 due to the appearance of centrifugal 7 and centripetal 8 forces, respectively, which will cause the excitation of additional resonant IGV 9 in ice. ) will cause a summation of their amplitudes (IGV profile 10).

Claims (2)

1. The method of destruction of the ice cover by an underwater vessel by exciting resonant flexural-gravitational waves in ice when it moves at a resonant speed and creating a region of reduced pressure under the ice cover at the location of the base of the flexural-gravitational wave by centrifugal forces from the rotation of the impeller located in the upper part hull, characterized in that under the ice cover create both a region of reduced pressure by centrifugal forces, and the region of increased pressure through ohms of centripetal forces from the rotation of the impeller, while centrifugal forces are excited by direct rotation of the impeller, and centripetal forces are changed by changing the direction of rotation of the impeller, moreover, changing the direction of rotation of the impeller is carried out repeatedly and periodically with twice the frequency of resonant bending-gravitational waves, and the duration of the direct and opposite rotations the impeller is equal to the half-period of resonant bending-gravitational waves. 2. The method according to claim 1, characterized in that the impeller blades have a curved shape characteristic of centrifugal pump blades.