RU2028649C1 - Method of protection against tropical cyclone - Google Patents

Abstract

FIELD: meteorology. SUBSTANCE: field of wind is measured when defining parameters of trajectory of tropical cyclone. Field of wind is used for determining position of zones with maximal retard and maximal value of tangential component of vortex rotation. Both zones or one of them is selected as zones of influence onto convective streams in cloud system of tropical cyclone. Influence is performed by artificial dissociation or regeneration of convective streams, as a result, cyclone is directed along safety route. EFFECT: improved precision; improved efficiency. 9 cl, 2 dwg

Description

 The invention relates to meteorology, in particular to active effects on cloud systems (convective clouds), and can be used to prevent (protect human life) from the effects of dangerous and especially dangerous phenomena, such as hurricanes (typhoons).

A known method of active action on cloud systems, in particular on a tropical cyclone [1]. The goal - the suppression of a tropical cyclone - is achieved by the fact that according to the proposed method, a region of intense ascending air flows limited by the cyclone's eye is covered with a monomolecular reagent layer (hexadexane). The main disadvantages of this method are the following:
disturbed ocean ecology and energy balance;
the cost of equipment and high reagent consumption.

Also known research program dedicated to the active impact on the hurricane, is the project "Storm Fury" [2]. The main concept of sowing in the Storm Fury project is the formation of a new cloud wall from clouds of rain strips by dynamic sowing. Cloud sowing is carried out using airplanes and special devices, which are small discharge pyrotechnic devices 250 mm long and 15 mm in diameter, containing 17 g of silver iodide in a mixture in which 78% A ₉ JO ₃ by weight. Sown clouds in the rain strip as a result of stimulation grow to the divergence region in the upper troposphere, while the increased inflow to the sea surface deflects the air from the surrounding eye of the cloud wall hurricane. The overall energy balance includes the additional supply of latent heat of condensation, and this is several times more than the direct supply due to freezing of supercooled water.

 The main fundamental drawback of the considered analogue is the neglect of changes in the trajectory of a hurricane, caused by an artificial change in its energy due to the active impact on cloud systems.

 The closest in technical essence to the proposed technical solution is a method of attenuation of tropical cyclones (hurricanes, typhoons) [3], which is selected as a prototype. In this method, the active effects are aimed at a more complete suppression of the energy of the hurricane in its central part. To do this, create a series of descending movements along concentric circles separated from the "eye" of the hurricane and from each other at a distance of about 10-15 km and with a step along circles of no more than 5-10 km for a time not exceeding the regeneration period of the upward movements of convective flows in the affected area. A series of explosions close to the “eye” of the hurricane initiates powerful downward movements, self-developing due to the internal energy of instability of the hurricane itself. In this case, the system of initiated downward movements is directed back to the natural circulation of the hurricane and thereby significantly weakens it.

 The main disadvantage of the prototype is the difficulty in suppressing the process of releasing energy of instability in the atmosphere and high material costs. In addition, the method, partially reducing the intensity of the hurricane, does not at all take into account the change in the trajectory and the speed of its movement after exposure with all the ensuing consequences.

 The aim of the invention is to reduce costs and increase reliability by ensuring the movement of a tropical cyclone in a safe direction.

 This goal is achieved by the fact that in the known method, when determining the parameters of the trajectory (the "eye" position, speed and direction of movement), the wind field is measured, which determines the position of the zones of maximum drag and the maximum value of the tangential component of the rotation of the vortex, both of these zones or one of they are selected as zones of influence on convective flows in the cloud system of a tropical cyclone, and the effect is carried out by artificial regeneration (formation of ascending x movement) or artificial dissipation (formation downward movements) of convective currents.

 The presence of new features in relation to the prototype allows us to conclude that the proposed method meets the criterion of "novelty."

 Known sources of information do not describe the operations carried out for purposefully changing the trajectory and speed of movement of vortex formations, therefore it is legitimate to conclude that the proposal meets the criterion of "significant differences".

 The fundamental difference between the proposed technical solution and the prototype lies in the basic concept of the method and consists in the fact that the effects on convective clouds are not produced to suppress the development of a tropical cyclone (as in [2] and [3]), but they carry out active control of the energy release process instability, taking into account the changes in the cyclone displacement vector after exposure.

 The proposed technical solution is based on a previously unknown regularity of the movement of a vortex formation in the atmosphere, which was established experimentally for the first time using the example of a convective cloud.

 The vortex formation in the atmosphere is shifted relative to the point of maximum inhibition by the largest in magnitude tangential component of rotation; the speed and direction of movement naturally vary depending on the potentials of the forces acting on the dynamic system of the vortex - external wind.

 Other previously known methods for calculating the displacement of tropical cycles, hurricanes, typhoons do not allow one to obtain a displacement vector from the data of the first observation (at least two observations are required with a time resolution from one to several hours), i.e. receive a vector as a tropical cyclone moved, which significantly reduces the efficiency of analysis and prediction of the development stage, and, consequently, the movement of a tropical cyclone.

 It was established (by mathematical modeling) that the main role in the formation of atmospheric vortex circulation belongs to the latent heat of vaporization in the rising air flow in convective clouds of developed forms. This circumstance marked the beginning of the search for technical solutions to weaken the tropical cyclone (typhoon) by actively influencing convective clouds in its cloud system.

On figa, b, c shows the kinematic diagram of the vortex - an external wind, which indicates the position of point A of maximum inhibition in various stages of the development of a dynamic system. The stage of development of a dynamic system is determined by the ratio of the vectors: external wind U _s , the tangential component of rotation U. The modules of these vectors are determined by the potentials of the acting forces: heterogeneity of the pressure fields, temperature, humidity, gravitational component, orographic obstacles.

The tangential component of vortex rotation is due to the release of instability energy in the air mass and is associated with the vertical component by the continuity equation:
div U _{x, y, z} = 0.

Obviously, if you act on the convective component (vertical U _z ), then this effect causes a change in the horizontal components U _x , U _y , and therefore the tangential component of the rotation of the vortex; the position of the point of inhibition - And also changes.

 In FIG. Figure 2 shows the wind field in a tropical cyclone; zones with maximum air velocity are identified. Combining the kinematic diagram of FIG. 1 with the wind field of FIG. 2, it seems possible to obtain a cyclone displacement vector from the available data. The calculated vector coincides in absolute value and direction with the real one given in the upper part of FIG. Therefore, the above regularity of the movement of the vortex formation in the atmosphere is valid for tropical cyclones.

 Following the basic concept of the proposed technical solution, active control of the process of energy release of instability, taking into account the changes in the vector of tropical cyclone displacement after exposure, the following procedure for performing technological operations is proposed.

 PRI me R. According to measurements (for example, Doppler radar), wind fields in a tropical cyclone receive a tachogram with maximum values of wind speed. On the tachogram, the position of the point of maximum inhibition is determined by the largest in magnitude tangential component of rotation -A. From this point through the center of the vortex draw a line of position of the vortex layer. All vectors in the vortex layer are parallel and directed normally to the position line. The vector of maximum velocity is constructed (on a scale) in the vortex layer on the side of the vortex opposite from point A. The beginning of this vector is indicated in figure 2 by point B, its position corresponds to the maximum value of the tangential component of the rotation of the vortex. The end of this vector is connected to point A, and a vector profile line is obtained in the vortex layer. A tropical cyclone displacement vector is constructed from the center of the vortex, which is directed normally to the position line and is limited by the line of the wind profile. The value of the module is obtained by translating its geometric length through a scale factor into units of measurement.

 If the tropical cyclone is shifting threateningly, then there is the possibility of choosing one of six combinations of operations aimed at changing its trajectory.

 Causing the regeneration of convective flows (artificial formation of upward movements) in the zone of maximum inhibition of the tangential component of the vortex rotation (in zone A), one deviates the trajectory of the tropical cyclone in the direction that coincides with the direction of rotation of the vortex. To the left with the cyclone formed in the northern hemisphere, and to the right with the cyclone formed in the southern hemisphere.

 By causing dissipation of convective flows (artificial formation of downward movements), in the same zone, the trajectory of the tropical cyclone is deflected in the direction opposite to the direction of rotation of the vortex. Right - with the cyclone that formed in the northern hemisphere, and to the left - with the cyclone that formed in the southern hemisphere.

 By causing regeneration in zone A and at the same time dissipation in zone B (the zone of the maximum value of the tangential component), they deviate the cyclone's trajectory in the direction that coincides with the direction of rotation of the vortex and transfer it to a loop-like trajectory with a simultaneous decrease in the speed of movement.

 By simultaneously regenerating convective flows in both zones, a deviation of the cyclone's trajectory in the direction coinciding with the direction of rotation of the vortex is achieved, and its transition to a loop-like trajectory with a simultaneous increase in the speed of movement.

 Causing the dissipation of convective flows in both zones at the same time, the path of the tropical cyclone is deflected in the direction opposite to the direction of rotation of the vortex with its transition to a loop-like path with a simultaneous decrease in the speed of movement.

 Causing dissipation in zone A and regeneration of convective flows in zone B, the trajectory of the tropical cyclone is deflected in the direction opposite to the direction of rotation of the vortex with a simultaneous increase in the speed of movement.

 If the tropical cyclone moves in a safe course near the protected object and there is a likelihood of its spontaneous course change, you should use one of the following two combinations.

 By causing the convective flows to regenerate in zone B, they achieve an increase in the speed of the tropical cyclone without changing course in order to get out of the area adjacent to the protected object as soon as possible.

 By causing dissipation in the same zone B, a decrease in the speed of the cyclone is achieved. The latter combination is advisable to apply in the case of a decaying cyclone in order to accelerate its destruction.

 The regeneration of convective flows in the clouds is caused by the introduction of small doses of an ice-forming reagent (silver iodide) or a refrigerant (solid carbon dioxide) into them. The reagent is introduced into the top of the cloud. The impact is carried out with a discreteness in time equal to or greater than the regeneration period of convective flows, which is determined by timing the change in the height of the upper boundary of the clouds, or using a radar. A sign of the beginning of regeneration is a clearly defined cloud peak growing in height (according to visual observations from an airplane). A sign of the place and time of introduction of the reagent can be the appearance on the top of the cloud of fibrous, vertically oriented structures (determined visually from the aircraft). The aircraft passes directly above the top of the cloud with an excess of 500-600 m above the upper limit so as not to have a negative effect due to dynamic impact by a satellite stream. The heat of phase transitions (condensation and crystallization) released as a result of active exposure enhances convective flows in the clouds.

 Dissipation (suppression) of convective flows is carried out by dropping to the top of a cloud of expandable packets of 20-30 kg in weight containing coarse powder with a specific area of at least 10 m / g. Coarse-dispersed powder particles, when falling, cause the development of downward movements, which cause the dissipation of the energy of instability and upward movements in the clouds. The exposure is repeated with a time resolution equal to or less than the regeneration period of convective flows in the clouds (approximately 15-20 minutes).

 Depending on the tasks set, the operations of the method should be carried out either until the tropical cyclone leaves the zone of the protected object, or until its energy is completely dissipated.

 The technical and economic efficiency of the proposed method lies in the fact that it allows not only to control the process of releasing instability energy in a tropical cyclone (hurricane, typhoon), but also to quickly take into account the change in the trajectory and speed of the cyclone after exposure. Thus, the implementation of the method allows you to protect (protect national economic objects and ensure human life in areas subject to the destructive activity of tropical cyclones (typhoons, hurricanes). The economic effect can be assessed as prevented damage.

Claims (9)

 1. METHOD OF PROTECTION AGAINST TROPICAL CYCLONE, including determining the parameters of the trajectory of a tropical cyclone, selecting zones of influence and performing periodic effects in these zones on convective flows in the cloud system of a tropical cyclone, characterized in that, in order to reduce costs and increase reliability by providing movement tropical cyclone in a safe course, when determining the parameters of the trajectory, a measurement of the wind field is made, according to which the position of the zones of maximum inhibition and max the maximum value of the tangential component of the rotation of the vortex, moreover, both of these zones or one of them are chosen as the zones of influence.  2. The method according to p. 1, characterized in that in the zone of maximum inhibition of the tangential component of the rotation of the vortex, the convective flows are regenerated, and the action is repeated until the trajectory of the tropical cyclone deviates in the direction that coincides with the direction of rotation of the vortex.  3. The method according to p. 1, characterized in that in the zone of maximum inhibition of the tangential component of the rotation of the vortex, the convective flows are dissipated, and the action is repeated until the trajectory of the tropical cyclone deviates in the direction opposite to the direction of rotation of the vortex.  4. The method according to p. 1, characterized in that, in order to increase the speed of movement of the tropical cyclone when it moves at a safe course, in the zone of the maximum value of the tangential component of the rotation of the vortex, convective flows are regenerated.  5. The method according to claim 1, characterized in that, in order to reduce the speed of movement of the tropical cyclone, in the zone of the maximum value of the tangential component of the rotation of the vortex, convective flows are dissipated.  6. The method according to p. 1, characterized in that in the zone of maximum inhibition and in the zone of maximum tangential component of the rotation of the vortex, respectively, the regeneration and dissipation of convective flows are caused, and the action is repeated until the trajectory of the tropical cyclone in the direction coinciding with the direction of rotation of the vortex and its transition to a loop-shaped trajectory with a decrease in the speed of movement.  7. The method according to p. 1, characterized in that in the zone of maximum inhibition and in the zone of maximum tangential component of the rotation of the vortex, the convective flows are regenerated, and the action is repeated until the trajectory of the tropical cyclone deviates in the direction that coincides with the direction of rotation of the vortex, and the transition its on a loop-shaped trajectory with an increase in the speed of movement.  8. The method according to p. 1, characterized in that in the zone of maximum inhibition and in the zone of the maximum tangential component of the rotation of the vortex, the convective flows are dissipated, and the action is repeated until the trajectory of the tropical cyclone deviates in the direction opposite to the direction of rotation of the vortex, and its transition on a loop-shaped trajectory with a decrease in the speed of movement.  9. The method according to p. 1, characterized in that in the zone of maximum inhibition and in the zone of maximum tangential component of the rotation of the vortex, respectively, dissipate and regenerate convective flows, and the effect is repeated until the trajectory of the tropical cyclone deviates in the direction opposite to the direction of rotation of the vortex, and its transition to a loop-shaped trajectory with an increase in the speed of movement.

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