RU2180777C1 - Method to eliminate migratory locust flocks - Google Patents

Abstract

FIELD: agriculture, pest control. SUBSTANCE: laser radiation of W power and aperture of S area is directed upon the part of flock's visible contour. The former should be fixed upon the selected part for the period of Δτ_i, during which all flock's individuals, being in laser radiation aperture, have got a destroying dose of radiation q. Moreover, Δτ_i= (q/W)•S. Then scanning is conducted by replacing radiation upon another part of flock's visible contour, moreover, the whole scanning time is determined by the ratio, τ = (F/S)•Δτ_i, where F - the area of flock's visible contour. To eliminate the flock at individuals' amount N and individuals' density n, laser radiation power is measured by the ratio:

where k=1-2.5 being the index of flock's shape. The method could be performed due to applying laser complex supplied with guidance systems and those of radiation scanning placed upon any transport vehicle. Laser complex could include chemical and CO₂-lasers, CO-lasers of open and closed types working at continuous or impulse-periodic modes. At scanning flock's visible contour by laser radiation it is necessary to direct it upon parts of the highest individuals' gathering to shorten the terms of flock's elimination. EFFECT: higher efficiency in eliminating migratory locust flock during the whole light-day period. 5 cl, 1 dwg _

Description

 The invention relates to the field of pest control of agricultural crops and can be used to destroy flying swarms of locusts.

 Locusts (order Orthoptera, suborder Caelifera, superfamily Acridoidea) are the most serious pests of agriculture in both the Old and New Worlds. Of particular danger are species that give herd migratory form with a high population density. These species are collectively called locusts or herd locusts. In the world there are more than a dozen species of locusts. Most of them periodically record outbreaks of mass reproduction, which cause enormous economic damage.

 In the life cycle of locusts, three characteristic periods can be distinguished. A period of mass egg laying in places called nesting grounds. The period of swifts, in which larvae (locusts) live in close clusters before fledging. And the flocking period, when locust individuals take wing and migrate over a long distance.

 In the first two periods, developed, mainly chemical, methods for the destruction of locusts exist [1]. In the flock period, locust destruction methods are not implemented. Since the 70s, in connection with the development of electromagnetic radiation sources, proposals have appeared to destroy insects, including locusts, using microwave radiation, microwave radiation and laser radiation.

So in [2] it is proposed to destroy pests of animal and plant origin by exposing them to microwave radiation. In [3], it is proposed to destroy these pests by exposing them to microwave radiation. These methods use electromagnetic radiation with a wavelength exceeding the size of the pests, and therefore, the destruction effect is achieved by heating the whole body of the individual to a temperature that causes the death of the insect. Such methods are unsuitable for destroying flying swarms of locusts. When an individual is heated to 100 ^o C (the temperature of deliberate necrosis of tissues), with a specific heat capacity of the insect body of 1 J / (g • g), energy consumption of 2-3 • 10 ⁴ kW • hour is required to destroy a span flock of locusts of medium size. This means that during the day flight of the flock ~ 12 hours, the power of the microwave or microwave source should reach 2000 kW. Sources of such power are fundamentally stationary and therefore not suitable for the destruction of locust flocks.

 In [4], it was proposed to destroy insects, including locusts, by laser radiation of various spectral ranges in a certain allocated volume, where they are attracted by baits of various types of action. This method is designed to kill a small number of attracted insects and is not suitable for controlling flying swarms of locusts.

In [5], selected as a prototype, a method is proposed for the destruction of locust flocks with a total biomass of up to 3000 tons, based on exposure to the flock with laser radiation. This method uses a mobile source of laser radiation (Nd-YaG laser, chemical laser, CO ₂ laser) with a power of up to 10 kW, operating in continuous or pulse-periodic modes. In this case, the laser is equipped with a special computer scanner, which resolves an individual individual in the flock by the pattern recognition method and tracks its movement, and the laser radiation focuses on the selected area of the insect body in a spot with a diameter of 2 mm. After that, the radiation is redirected to the neighboring individual.

 The proposed method for the destruction of flying swarms of locusts is not technically feasible.

The characteristic number of individuals in the migratory flock of locusts is N ~ 10 ⁷ -10 ⁹ pieces with an individual density of n ~ 10 ^-3 -10 m ^-3 . The mass of the locust specimen is ~ 3 g. The typical biomass in the flock is up to 3,000 tons. The time the flock is in flight is ~ 12 hours a day. Our experimental studies have shown that the energy density q, which causes irreversible damage to an locust individual, weakly depends on the wavelength of the laser radiation and amounts to ~ 3 J / cm ² . In the method proposed in [5] for the destruction of migratory flocks of locusts with a spot diameter of 2 mm (spot area 3 • 10 ^-2 cm ² ), the energy required for irreversible damage to a locust individual is 0.1 J. Formally, a laser has a radiation power of up to 10 kW per time being in flight (without taking into account the time of radiation redirection to the next individual) is capable of destroying the flocks of the above sizes, however, only under one condition, when the radiation energy is supplied sequentially to each locust individual. Technically, it is not possible to implement such a method of energy delivery to an individual locust.

In fact, when placing the radiation source on the vehicle, to ensure the safety of its operation, it is necessary to maintain a certain distance between the source and the pack. The size of an individual locust is 3 to 7 cm in length and up to 1 cm across. If the distance between the radiation source and the pack is 1 km, then the angular visibility of the locust specimen is 10 ^-5 rad. This means that the angular accuracy of the retention of the focused spot should be no worse than 5 • 10 ^-6 rad. This value is the limit of pointing accuracy for a dry, windless, slightly turbulent atmosphere. In real conditions, such accuracy is unattainable, especially since the vehicle’s own vibrations obviously hinder the achievement of a given accuracy of radiation guidance. Thus, the method according to [5] will not be able to solve the problem of the destruction of flying swarms of locusts.

 The technical result of the invention is to increase the effectiveness of the fight against flying swarms of locusts up to their complete destruction through the use of a technically feasible method of scanning the flock with laser radiation.

где k=1-2.5 - коэффициент формы стаи.The specified technical result is achieved by the fact that in the method of destroying migratory flocks of locusts, which consists in exposing the flock to laser radiation with subsequent scanning, laser radiation with a power of W and an aperture of area S is directed to a section of the visible contour of the flock, fixed in the selected section for the time Δτ _i ,, during which at a given laser power, all individuals of the pack, the pack located in the region inside the aperture of the laser beam passing through a flock is obtained strikes dose q, wherein _{Δτ i = (q / W)} • S, Zateev is scanned by moving the radiation on the other portion of visible flocks circuit, wherein the full scan time τ is given by τ = (F / S) • Δτ i, where F - visible flocks circuit area, while for the destruction of flocks with the number of individuals N and a density of individuals n the power of laser radiation is determined by the ratio:

where k = 1-2.5 is the coefficient of the form of the flock.

The method is illustrated in the drawing, which shows a flock of locusts moving at a speed U, with a visible contour area F, to a portion of which laser radiation with an aperture area S is directed. The method according to the invention does not require laser radiation to be directed to each individual of the flock, however, it implementation requires values of radiation power greater than in the prototype. Indeed, laser radiation with a maximum power of W = 10 kW, adopted in [5], is capable of destroying only 50 tons of biomass in a full day flight of a flight of ~ 12 hours (estimates were carried out according to the formula for W, taking k = 1, n = 10 m ³ and q = 3 J / cm ² ). Those. more powerful lasers are required to destroy flying swarms of locusts.

Such laser sources include chemical, CO ₂ , and CO lasers. CO lasers emit in the spectral range from 4.7 μm to 7 μm. It was experimentally shown [6, 7] that electric-discharge CO lasers have the highest values of efficiency (coefficient of conversion of electric power to laser radiation power of more than 40%) and specific energy consumption (more than 100 kW / (kg / s)). With such energy characteristics, the laser’s mass and size indicators allow you to create complexes that can be placed on vehicles - land, water and air.

 The CO laser can be open or closed loop. An open-cycle laser is structurally simpler and allows you to enter the mode in a shorter time. However, with prolonged operation, an open cycle requires large reserves of the working fluid. A closed-loop laser does not require supplies of a working fluid, however, until a certain exposure time, which does not require large supplies of a working fluid, it remains heavier than an open-loop laser and has a longer exit time. The choice of laser circuitry is determined by the size of the pack and the carrying capacity of the vehicle. The larger the flock size, the longer the exposure time for the flock and, accordingly, the supply of the working fluid of an open-cycle laser should be larger. If the vehicle's carrying capacity is limited or the flock to be destroyed is large, requiring a long exposure time, a closed-loop laser should be used, as it does not require a supply of working fluid.

 To achieve a technical result according to the invention, it is possible to use both a continuous laser radiation mode and a pulse-periodic mode. Continuous radiation is technically easier to implement. In the pulse-periodic mode of radiation, the effect of the destruction of locusts is higher due to the fact that at the same average power the radiation power in the pulse is higher, which increases the efficiency of the defeat.

 If it is possible to isolate areas of the condensation of individuals in the flock, it is advisable to direct continuous or pulse-periodic laser radiation to them. This reduces the time of the destruction of the flock.

 The redirection of radiation in the case of a pulsed-periodic mode can be done during the time between radiation pulses, which will also reduce the time of destruction of the flock.

 The method according to the invention proposes to influence the flock of locusts at different times of its daily cycle. The daily behavior of the flock is as follows. After sunrise, the flock that has landed in a compact formation for the night is basking in the sun for 2 hours, with some of the flock taking off and swarming above the seated main pack. The whole flock rises into the air over the next 2 hours. In a daytime flight, members of a flying flock repeatedly land and take off, resulting in a continuous rotation of locusts. This leads to the fact that it is possible to destroy the flock of locusts in parts, that is, as it periodically rises into the air both during the swarm and during the flight, which is more beneficial energetically. It should be noted that, determining the topology of the take-off part of the flock, highlighting the places in the contour of the flock with the largest number of individuals and directing destroying laser radiation to these places, it is possible to deprive the flock of the ability to collective behavior, since it is presumably in the places of accumulation of the most probable presence of dominant individuals that determine the behavior flocks. A flock incapable of collective behavior is deprived of the possibility of further advancement and can be destroyed by other means.

 Thus, the existing laser systems located on any vehicle equipped with guidance systems and scanning laser radiation, allow to implement the method according to the invention, which allows you to destroy the flock of locusts.

Sources of information
1. Locusts - ecology and control measures. - Ed. "Science", L., 1987, pp. 40-65, 78-110.

2. The patent of Germany 3719994 A1, cl. MKI ⁴ A 01 M 1/22, published. 12/29/88.

3. The patent of Germany 3804052 A1, cl. MKI ⁴ A 01 M 1/22, published. 08/24/89.

4. US patent 5343652, CL. MKI ⁵ A 01 M 1/20, published. 09/06/94.

5. The patent of Germany 3825389 A1, cl. MKI ⁴ A 01 M 1/22, published. 02/08/90 (prototype).

 6. Continuous electroionization CO laser with a subsonic flow of the working mixture. A.S. Golovin, V.A. Gurashvili, et al. Quantum Electronics, 23, 5, p. 405-408.1996.

 7. Dymshits B.M., Ivanov G.V., Mescherskly A.N. CW 200 kW supersonic CO Laser. SPIE, vol. 2206, p. 109-120, 1999.

Claims (6)

1. A method of destroying flying swarms of locusts, which consists in exposing the flock to laser radiation followed by scanning, characterized in that the laser radiation with a power of W and an aperture of area S is directed to a section of the visible contour of the flight, fix it on the selected section for the time Δτ _i , in during which at a given laser power, all individuals of the pack, the pack located in the region inside the aperture of the laser radiation passing through a flock is obtained strikes dose q, wherein _{Δτ i = (q / w)} • S, then is scanned by moving the light- Nia to another portion of visible flocks circuit, wherein the total τ scanning time is given by τ = (F / S) • Δτ i, where F - area of visible flocks circuit, wherein for the destruction of flocks with the number of individuals N and a density of specimens n power of the laser radiation determined by the ratio

where k = 1-2.5 is the coefficient of the form of the flock.  2. The method according to p. 1, characterized in that the flock is exposed to continuous radiation of a CO laser of an open or closed loop.  3. The method according to p. 1, characterized in that the flock is affected by pulse-periodic radiation of a CO laser of an open or closed loop.  4. The method according to PP. 1 to 3, characterized in that the scanning is carried out by moving the laser radiation in areas of condensation of individuals in a flying flock.  5. The method according to PP. 1 to 3, characterized in that the scanning is carried out by moving the laser radiation in areas of the concentration of individuals in the swarm flock.  6. The method according to PP. 1 - 5, characterized in that during the scanning process, the laser radiation is moved to another part of the visible contour of the flock during the time between radiation pulses.