FR3034672A1 - TARGETED AND OPTIMIZED AUTONOMOUS EMISSION SYSTEM FOR SEMIO CHEMICAL SUBSTANCES - Google Patents

Abstract

The present invention relates to an autonomous system for targeted and optimized emission of semiochemical substances. It is an electronically assisted autonomous system for the targeted and optimized distribution by evaporation of semiochemical substances diffused at spatially separated locations and at specific times for the control of pests in specific areas of crops to be treated including: a ) a gasification column (1) of at least one semiochemical substance comprising volatile: b) an air generator (2) connected to the gasification column (1) by a solenoid valve (2.1); c) at least one flexible diffusion pipe (7) fitted on the quick coupling of the solenoid valve (6.2); d) at least one ambient factor sensor; e) an electronic control module (9); f) an electric generator (8) The semiochemical substances used are kairomones.

Description

The present invention relates to an autonomous system for targeted and optimized emission of semiochemical substances. More particularly, the present invention relates to an electronically assisted autonomous system for the targeted and optimized distribution by evaporation of semiochemical substances diffused at spatially separated locations and at opportune times, for the control of pests in specific areas of cultures to be treated. It is known that semiochemicals are continuously diffused into space to develop their pest control activity in a space to be treated during the agricultural productive season until the source of said substances is exhausted. Several known systems make it possible to obtain a slow and continuous release of these substances. They are generally in high boiling liquid solutions, used as such or absorbed on different supports: they are non-porous polymeric matrices in monolayer or in multilayers containing the active principle, microcapsules with polymeric envelope (US 3,577,515). ) or in gel (US 2,800,457 and US 2,800,458) containing the active ingredient, woven or nonwoven fabric containing the active ingredient (FR 2 722 368), or hollow fibers containing the active ingredient (GB 2 161 138 and US 4,017,030).

Most of these systems proceed from the passive diffusion of the active principles by simple atmospheric evaporation. They are therefore not completely satisfactory considering that the kinetics of release of the active ingredients is fluctuating according to the ambient factors that influence evaporation, such as temperature, humidity and the speed of movement of the air. These systems therefore do not allow the rate of release of the active ingredient to be regulated for optimized efficacy. Another disadvantage of these systems is that in the case where the co-formulants, the active ingredient (s) and the diluent forming the active chemical composition do not have the same evaporation temperatures, the said composition is modified. as individualized evaporation of the active ingredient and the other components. As the amount of active solution remaining can not be properly evaluated, the actual duration of activity of these systems remains uncertain to predict. Their operation is not optimized. Systems for controlling the diffusion of volatile substances are known. These are heating systems that allow controlled evaporation of the active ingredient which is usually in liquid solution: electric radiator heating system (EP 1 101 500) or convector (NO 2013 116 565). There are more and more wick systems, more easily controllable by heating only the liquid solution found in the wick by various electric heating systems, this system also being that of the said electronic cigarette (EP 1 101 500; WO 2013/116571, EP 1 579 762, EP 1 372 161, EP 1 108 358, EP 2 481 308 and EP 2 260 733). The electric heating system is also used for heating a liquid solution tank which requires the heating to be uniformly distributed to obtain a constant composition vapor (US 2001/0020450, US 2007/0257016). These systems certainly operate on demand, but not autonomously for the determination of the start time and the operating time. The diffusion of the active principle in several points can be done by several devices each placed at these diffusion points, which does not guarantee a fair distribution of said active ingredient in an area to be treated. Moreover the manpower for the installation and the maintenance of these systems is important. A particular system for diffusion of active substance by heating (US 6309986) describes a device composed of a support layer impregnated with the active substance and placed on a metal plate which is connected to a heat generator. The capacity of this device can be increased by the superposition of active layers interposed with heating plates. But this system which favors the placement of the active substance in a solid protective support unlike systems using directly heated liquid substances, has at least three major disadvantages: the diffusion of the active substance can be done in one point of the space to be treated; during operation, the thermal inertia of the metal plates contributes to prolonged heating of the support, which can lead to denaturation of the active substance; on the exploitation side, there is a difficulty of control of diffusion because of lack of enough parameters on which one could act. Another major drawback is that because of the difficulty of controlling the diffusion of the active substances as well as the lack of possibility of putting the device into operation without the intervention of the man at the appropriate moment, this system, just like the others already mentioned, can not provide an action with optimized effect from the point of view of the duration and the intensity of the action, to treat optimally determined zones.

A common disadvantage of most known unmanned systems is that the forced diffusion by heating volatile active substances lasts only a few hours, while the passive diffusion which is done according to the ambient factors lasts the time of a season without control and without interruption, even when there are no harmful insects to control. The activity of these systems is not optimized. Japanese Patent JP 3,498,858 (B2) to EARTH CHEMICAL CO describes a volatile chemical diffusion apparatus supported in paste or fabric and disposed in a filter-effect plate device. This device is placed in a tubular body provided with a fan placed under the plate carrying the volatile chemical substance and which propels air through said support plate. The air is charged with volatile substance which is thus immediately transported outside through exits. This apparatus does not make it possible to store the volatilized substance in order to control the diffusion concentration in an optimal manner by regulating said concentration in the diffused charged air. On the other hand, there is no disclosure of the possibility of diffusing the volatile chemical into areas remote from the diffusion apparatus. Neither are the ambient factors which can disturb and reduce the action of the active substance are taken into account. The device according to this patent is not automated because it requires a human presence for its implementation at the appropriate time. The object of the present invention is an electronically assisted autonomous system for the targeted and optimized emission of semiochemical substances for the programmed control of pests in specific areas of cultures to be treated.

The control of the emission of the semiochemical substance is done in a targeted way in the precise zone to be treated on the basis of the information on the ambient factors provided by sensors analyzing the luminosity, the temperature and the humidity of the air, as well as the presence or absence of the wind and its direction. Indeed the brightness can be located in the divisions of the day in dawn, day, dusk and night. The humidity of the air may be indicative of a rainy moment that may make the emission of the semiochemical substance useless or improbable, as well as a wind that is too strong and / or has a disadvantageous orientation for the effect of said substance. on the pests. The duration and parameters of the emission are specifically predetermined according to the physiology of the pest to be controlled.

Surprisingly, the system according to the invention as well as its various variations make it possible to achieve the targeted diffusion of semiochemical substances in the zone to be treated optimally without direct human intervention, thanks to a set of automatically controlled devices. Indeed, for example, to control harmful insects in one hectare of plantation during a season of 140 days, the system according to the invention consumes only 10% to 50% of pheromone, or 50% to 90% less by compared to an existing conventional device to cover the same period. Indeed, since the majority of pests - such as moths - are nocturnal, mating disruption only needs to be in operation at night, when environmental factors are conducive to finding partners. Advantageously, with for example the 130 g of sex pheromone currently used for a treatment of 1 ha for 140 days (see Ginko and ISOMATE C), the system according to the invention, by consuming in an optimized manner that The amount of pheromone between 13 g and 65 g necessary and sufficient for treatment in 140 days is capable of prolonging the treatment period up to 300 days. This characteristic confers on the system of the invention an immediate reactivity in the case where there is an offset in the season, for example the phenomenon of the Indian summer or a delay in maturation of cultures prolonging the risks of infestation. . In this case, it is not necessary to recharge the semiochemical substance or to change the device, which is not possible with the devices previously mentioned. Another objective of the invention is to provide a system having a durability and an organizational uniqueness of the devices that compose it, insofar as said system is usable for several years, renewing only the semiochemical substance, the whole remaining in square.

This objective is also embodied by a saving in application time with respect to the laying stress as well as relief of many individual broadcasting devices. Indeed, currently at least 500 devices per hectare, independent of each other are necessary to provide acceptable efficiency, which requires a significant workforce. In addition, accidental stalling or forgetfulness in the field of these devices entails the risk of environmental pollution. Another objective of the system according to the invention resulting from the durability of the installation is the optimal and uniform positioning of the diffusion of the semiochemical substances. Said diffusion must indeed be carried out in the upper third of the canopy in the case of fruit trees, which is not always physically easy to achieve with the current systems. This positioning of the system according to the invention can also be facilitated by coupling it to physical protection structures, such as nets, already installed in certain cultures. The consumption of semiochemicals by the system according to the invention is reduced by being between 10% and 50% of current consumption to obtain an acceptable efficiency. The system according to the invention makes it possible to achieve a strong management economy compared to the system of currently used devices. Similarly, this small quantity of semiochemical substances emitted makes it possible to limit the risks of air pollution by reducing emissions of 30 VOCs. The present invention has a first object consisting of an electronically assisted autonomous system for the targeted and optimized distribution of semiochemicals at spatially separated locations and at specific times for the control of pests in specific crop areas. treat.

For a better understanding of the object of the invention, Figure 1 not to the scale that follows is given by way of example. It represents a vertical side section of the system according to the invention. More specifically, the system according to the invention is realized by means of a combination of electronically controlled devices comprising: a) a gasification column (1) of at least one semiochemical substance; b) an air generator (2) connected to the gasification column (1) by a solenoid valve (2.1); c) at least one flexible diffusion pipe (7) fitted on the quick coupling of the solenoid valve (6.2); D) at least one ambient factor sensor; e) an electronic control module (9); f) an electric generator (8). The gasification column is preserved from outside climatic conditions to the system by an insulated wall, to avoid any chemical modification of the active molecules of the semiochemical substance which is gasified and stored prior to its diffusion. Said column (1), whose parts forming the body are secured to each other by clips or by any other securing means, consists of: L a gasification chamber (4) of the insulated wall chemical substances located in the upper part of said column (1) and provided with a removable openwork container (5) carrying at least one semiochemical substance in solution or suspension incorporated in a polymer matrix (5.1) in the form of granules or particles, or placed in the form liquid in an open container; IL a cover (4.1) with heat-insulated wall closing the gasification chamber (4) from above; 3034672 - 7 - M. a heating chamber (3) with heat-insulated wall, situated in the lower part of the column (1), in the extension of the gasification chamber (4) and provided with an element heating element (3.3) and at least one temperature (3.1) and pressure (3.2) probe; / V. a nurse (6) with insulated wall, connected to the gasification chamber (4) by the main outlet electrovalve (6.1) and provided with several outlets each equipped with an outlet solenoid valve (6.2) ending with a quick coupling ; V. at least one air purge valve (6.3) for purging the nanny (6) and the diffusion pipes (7); The flexible diffusion pipes (7) are pierced with orifices (not shown) of small diameter, on the segments of said pipes (7) located in each zone to be treated. Said diffusion pipes (7) being fitted on the quick couplings of the nurse (6) and terminate in a closed end also pierced with small diameter orifices. Said diffusion pipes (7) are arranged in radiating formation starting from the cabinet housing the gasification column towards the locations corresponding to the zones to be treated preferentially. External sensors (not shown) for collecting information on ambient factors such as brightness, temperature and humidity, as well as the presence of wind, are connected to the electronic control module 20 (9). ). The electronic control module (9) is connected to all the organs providing the technical information and those to be controlled to ensure the automatic operation of the system. The electric generator (8) is rechargeable battery by the public electricity network or by solar panels (not shown), said electric generator (8) being connected to an electronic power unit (not shown) through which all the connections with the various members of the system, itself being connected to the electronic control module (9) for its control. A cabinet (not shown) houses the gasification column (1), the electric generator (8) and the electronic control module (9), said cabinet having orifices corresponding in position and in number to the outlet solenoid valves. (6.2) and of diameter adapted to the outside diameter of the diffusion pipes (7) coming out of it. According to an operating mode of the object of the present invention, the air generator (2) controlled by the electronic control module (9) provides an air flow of about 3000 L / h, air which is propelled via the solenoid valve (2.1) and heated in the heating chamber (3) by the heating element (3.3) to a predefined temperature as a function of the programmed evaporation temperature of the semiochemical substance and taking into account the glass transition temperature of the polymer matrix serving as a support. The air thus heated advantageously makes it possible to release at controlled rate and duration the semiochemical substance which is thus rendered in the gaseous state in the gasification chamber (4) where the gas is stored before its diffusion and between two moments. of broadcasts. Heating the polymer matrix by heated air to near its glass transition temperature promotes an increase in the gaseous release rate of the semiochemical substance from the polymer matrix. This release rate may be varied by a moderation of the experimentally determined temperature. In addition, said release rate varies in a manner directly proportional to the temperature of the heated air. Said product gas accumulates in the gasification chamber (4) when the outlet solenoid valve (6.1) is closed. It is diluted in the air produced by the generator (2) to arrive at a sufficient propulsion pressure in the nanny (6) when the solenoid valve (6.1) is open. The level of the pressure is determined experimentally as a function of the number and dimensions of the diffusion pipes (7) in operation, as well as the number and dimensions of the diffusion orifices. Then said active substance-rich gas is diffused into the atmosphere by each of the diffusion pipes (7) by the open solenoid valve (6.2) according to the program controlled by the electronic control module (9). According to a mode of operation of the system of the invention, the number of diffusion pipes (7) to be put into function is selected in a targeted manner with respect to the only areas to be treated infested by harmful insects, this number being between 1 and all of said pipes (7). The solenoid valves (6.2) open and close independently of one another at an opening duty cycle (OCR) received from the electronic control module (9). Like all the solenoid valves of the diffusion system according to the invention, the solenoid valves (6.2) operate in pulsed mode according to the principle of pulse width modulation (PWM) based on the frequency modulation and the sliding mode. The frequency and the width of the pulses controlled by the electronic control module (9) define the diffusion rate of the active gas by the diffusion pipes (7). According to one embodiment of the invention, the diffusion pipes (7) have an internal diameter of between 10 mm and 20 mm, their length varying between 40 m and 150 m according to the adopted configuration of distribution in the area to be treated.

The technical cabinet from which the diffusion pipes (7) leave is placed in the center, at the periphery, or at an angle of the field to be treated. According to a preferred embodiment of the invention, the diffusion orifices, with a diameter of between 0.2 mm and 2 mm, are distributed over the segmental portions of the diffusion pipe (7) located at the level of the only zones infested with treat.

According to another embodiment of the system, in the case of tree processing, said segmental portions are located in the canopy of each shaft traversed by the diffusion pipes (7) which are arranged on the branches passing from a tree. to another in the plots of the field to be treated. Segments outside the canopy do not carry diffusion holes.

According to a preferred mode of operation of the diffusion system of the invention, during the gasification of the semiochemical substance and then its diffusion in the gaseous state, the purge solenoid valve (6.3) remains closed. While during the air purge of the nanny (6) and diffusion pipes (7), the purge solenoid valve (6.3) is open while the solenoid valve (2.1) and the outlet solenoid valve (6.1) are closed. According to an advantageous feature of the invention, the diffusion orifices are placed only in the areas of the crop solicited by the harmful insects where the diffusion must be done optimally. The diffusion of the semiochemical substance takes place only at the precise moment provided by the automatic program, taking into account the ambient factors provided by the external sensors and automatically analyzed by the electronic control module (9) which manages the diffusion of the semiochemical substance. The solenoid valve (6.2) of the pipe (7) to be actuated then opens automatically to allow the emission. This lasts for the time that the solenoid valve (6.2) remains open automatically, taking into account the parameters induced by the factors analyzed by the electronic control module (9), in relation to the predetermined necessary transmission duration corresponding to the physiology of the insect pest to control. Said duration varies from 3 hours to 12 hours per day, at times corresponding to the activity of the pests in the area to be treated.

According to a preferred embodiment of the invention, the semiochemical substance is dissolved or suspended in a lipophilic solvent or dispersant liquid, and then said solution or suspension is incorporated into a polymer matrix. Said semiochemical substance is chosen from kairomones of natural origin or of synthetic origin. These are, for example, sexual pheromones intended to cause sexual confusion in pests such as those in the non-exclusive summary list of the insect / pheromone pairs chosen from: Cydia pomonella, Cydia fagiglandana, Cydia nigricana, Cydia splendana, Cydia strobilella and Cydia trasias: E8-E10-dodecadien-1-ol, 1-dodecanol, 1-tetradecanol-Cydia molesta: 8-dodecenyl acetate-Lobesia botrana and Eupoecilia ambiguella: Z9-dodecenylacetate, E7-Z9-dodecadienylacetate-Planococcus ficus: (S) - (+) - lavandulylsenecioate 30 - Grapholita molesta: (Z) -8-dodecen-1-yl-acetate, (E) -8-dodecen-1-yl-acetate, (Z) -8-dodecenate 1-ol - Keiferia lycopersicella (E) -4-tridecenyl acetate; Pectinophora gossypiella (Z, E) -7,11-hexadecadienyl acetate, (Z, Z) -7,11-hexadecadienyl acetate; 3034672 - Neodiprion sertifer 3,7-dimethyl-2-pentadeanol; - Amyelois transitella (Z, Z) -11,13-hexadecadienal, (Z, Z) -11,13-hexadecadien-1-01, (Z, E) -11,13-hexadecadien-1-ol, (Z, Z, Z, Z, Z) -3,6,9,12,15- tricosapentaene; 5 - Ceratitis capitate: 3,4-dihydro-2h-pyrrole; Bactrocera oleae: 1,7-dioxaspiro [5.5] undecane; Acrolepiopsis assectella: (Z) -11-hexadecenal, (Z) -11-hexadecenyl acetate; Adoxophyes honmai, Adoxophyes orana, Adoxophyes orana fasciata and Adoxophyes reticulana (Z) -11-tetradecenyl acetate, (Z) -9-tetradecenyl acetate; Agrotis segetum (Z) -7-dodecenyl acetate, (Z) -9-tetradecenyl acetate, (Z) -5-dodecenyl acetate, (Z) -5-decenyl acetate; Anthonomus grandis: cis-2-isopropenyl-1-methylcyclobutaneethanol, (Z) -2- (3,3-dimethyl) -cyclohexylideneethanol, (E) - (3,3-dimethyl) cyclohexylideneacetaldehyde, (E) -2- hexen-1-ol, (Z) - (3,3-dimethyl) cyclohexylidene acetaldehyde; - Aphis gossypii: E-beta-farnesene; - Archips argyrospila, Archips breviplicanus, Archips fuscocupreanus, Archips podana, Archips rosana and Busseola fusca: dodecyl acetate, (Z) - 11-tetradecenyl acetate, (E) -11-tetradecenyl acetate, tetradecyl acetate, (Z) -9- tetradecenyl acetate; Chilo suppressalis: (Z) -11-hexadecenal, (Z) -9-hexadecenal, (Z) -13-octadecenal; Diabrotica undecimpunctata howardi: 10-methyltridecan-2-one; Diabrotica barberi and Diabrotica virgifera virgifera: 8-methyldecan-2-ylpropionate; - Dioryctria merkeli: (Z) -9-tetradecenyl acetate; Dioryctria amatella: (Z, Z, Z, Z, Z) -3,6,9,12,15-pentacosapentaene, (Z, E) -9,11-tetradecadienyl acetate; Grapholita funebrana, Grapholita molesta and Grapholita prunivora (Z) -8-dodecenyl acetate, (E) -10-dodecenyl acetate, (E) -8-dodecenyl acetate; Heliothis maritime adaucta: (Z) -11-hexadecenal, (Z) -11-hexadecen-1-ol, hexadecanal; Heliothis virescens: (Z) -11-hexadecenal, (Z) -11-hexadecen-1-ol, (Z) -9-tetradecenal; Pandemis heparana, Pandemis limitata and Pandemis pyrusana (Z) -11-tetradecenyl acetate, tetradecyl acetate, (Z) -9-tetradecenyl acetate, (Z) -11-tetradecen-1-ol, dodecyl acetate; Platynota flavedana, Platynota idaeusalis and Platynota stultana: tetradecyl acetate, (Z) -11-tetradecenyl acetate, (E) -11-tetradecenyl acetate, (Z) -11-tetradecen-1-ol, (E) -11-tetradecen -1-ol, tetradecan-1-01; Orgyia leucostigma: (Z) -6-heneicosen-11-one, (Z) -6-heneicosen-11-one, (Z, Z) -6,9-heneicosadien-11-one, (Z) E) -6,8-heneicosadien-11-one, (Z, E) -6,9-heneicosadien-11-one; Ostrinia fumacalis: (E) -12-tetradecenyl acetate, (Z) -12-tetradecenyl acetate, tetradecyl acetate; Ostrinia nubilalis: (Z) -11-tetradecenyl acetate, (E) -11-tetradecenyl acetate; - Tetranychus urticae: (E, Z) -3,7,11-trimethyl-2,6,10-dodecatrien-1-o1, (Z) -3,7,11-trimethyl-1, 6, 10-dodecatrien 3-ol, 3,7-dimethyl-6-octen-1-01, (E) -3,7-dimethyl-2,6-octadien-1-01; Tuta absoluta: (E, Z, Z) -3,8,11-tetradecatrienyl acetate; - Synanthedon exitiosa, Synanthedon pictipes, Synanthedon myopaeformis, Synanthedon scitula and Synanthedon tipuliformis (Z, Z) - 3,13-octadecadienyl acetate, (E, Z) -3,13-octadecadienyl acetate, (Z, E) -3,13 octadecadienyl acetate; Rhyacionia frustrana and Rhyacionia zozana and Rhyacionia buoliana: (E) -9-dodecen-1-ol, (E) -9,11-dodecadienyl acetate, (E) -9-dodecenyl acetate; Spodoptera exigua (Z) -11-hexadecenyl acetate, (Z) -9-tetradecen-1-ol, (Z, E) -9,12-tetradecadienyl acetate; Spodoptera frugiperda: (Z) -7-dodecenyl acetate, (E) -7-dodecenyl acetate, 20 (Z) -9-tetradecenyl acetate; Spodoptera littoralis (Z, E) -9,12-tetradecadienyl acetate, (Z, E) -9,11-tetradecadienyl acetate. According to one aspect of the invention, the polymer is of natural origin, synthetic, still biosourced or a mixture thereof, in all cases it is biodegradable or non-biodegradable. The loading of said substance into the polymer matrix is carried out in accordance with the active polymer technology developed by the applicant in its laboratories. Said loading technology is disclosed and protected by the patents FR 2 901 172B1, FR 2 921 541B1, FR 2 956 345B1, FR 2 959 100B1, FR 2 983 075B1, FR 2 992 325B1, FR 2 990 942 and FR 1402377, properties of the plaintiff. This technology makes it possible to control the delivery of the active ingredient incorporated in the polymer matrix, said delivery taking place in a quantity dosed at a determined rate and for a long time. The active ingredient in the matrix is protected from the effects of environmental factors and excessive evaporation. According to one aspect of the invention, the polymers forming the matrix loaded with semiochemical substance are of natural or synthetic origin, or a mixture thereof. The polymers of natural origin are chosen, without this list being exhaustive, among the proteins proteins, lignocellulosic or proteinellocellulosic, lignocellulosic, cellulosic and their derivatives. Polymers of natural origin from the materials that make up these materials can also be used, including agro-industrial by-products such as sunflower, soy or grape seed cakes, coffee grounds, bran wheat, reduced corn cob, porosified cereal grains, reduced cork, wood chips, and milled or granulated wheat or corn flours. Reduced absorbent minerals such as bentonite, kaolinite or sepiolite can also be used. The polymers of synthetic origin according to the invention are chosen from the absorbent grades of polyolefins, polyamide and its derivatives, polyethylene and its derivatives, polyurethane, polyvinyl chloride, acrylates or polyesters, as well as copolymers and associations of these. According to one embodiment of the invention, the level of semiochemical substance incorporated in the polymer matrix varies between 5% and 40% by weight, depending on the nature of both said matrix and said substance. The flow of semiochemical substance emitted per day and per hectare by the system according to the present invention varies between 150 mg / day / ha and 300 mg / day / ha, preferably between 170 mg / day / ha and 240 mg / day / ha. against 930 mg / day / ha emitted by the devices currently used.

Accordingly, another advantage of the system according to the invention is that the semiochemical substances are delivered in metered quantities, just sufficient to obtain the effectiveness necessary for the control of harmful insects, without constantly saturating the ambient air with volatile organic compounds ( VOC) by unnecessary excess, which minimizes the risk of environmental pollution. According to another embodiment of the invention, the semiochemical substance is dissolved or suspended in a lipophilic solvent or dispersant liquid, then said solution or suspension is loaded into a container placed in the removable container. According to one embodiment of the invention, the devices of the system thus defined are designed in such a way that the various members are easily disassembled for their maintenance. According to one embodiment, the system according to the invention can be duplicated in the space to be treated to optimally cover the control of harmful insects of an entire plantation of several hectares. A second object of the present invention is to provide a method for controlling pests at spatially different locations at the same time in the crop fields using the electronically assisted autonomous system described above which consists in installing said system. either in the middle 15 or at the periphery of the fields to be treated so that the diffusion pipes (7) are arranged in radiating formation towards the locations corresponding only to the zones to be treated. In order to better understand the present invention and to put it into practice, some nonlimiting examples are given below by way of illustration.

EXAMPLE 1 It should be recalled that the sexual mating treatment of peaches against codling moth (Cydia pomonella) is spread over a season of about 140 days. Currently to treat 1 hectare of a peach orchard is used about 1000 diffusers marketed under the trademark lsomate® C (SumiAgro) with the following data: - the capacity of each diffuser is 260 mg of pheromone which is a mixture of Codlemon ®, dodecanol and tetradecanol; the quantity of pheromone consumed in 1 season per hectare is 130 g / season, ie 0.93 g / day / ha and 38.7 mg / h / ha; - Isomate® C diffusers are hung individually on the branches of peach trees to be treated. Application of the system according to the present invention In a plot of apple trees of 1 ha measuring 100 mx 100 m of sides, the system according to the invention is arranged as follows: a technical cabinet is placed in a corner of the plot to be treated in which are housed: an electronic control module to which all the electronically controlled components, all the probes and the sensors of the ambient factors are connected; - an electric generator with 100 Ah battery and a 300 W solar generator with electronic control and supplying electrical current at 12 V all the electrical elements of the system; a 3000 Uh flow air generator connected to the gasification device 15 via a solenoid valve; - a pheromone gasification device with a volume of 20 L, equipped with a heating resistor placed in the air heating chamber whose temperature is controlled by means of a temperature probe, and a gasification chamber provided with a pressure probe, in which is disposed a container in the form of a perforated metal basket with a high edge. The gasification chamber is capped with a removable cover retained by clips; the assembly is connected via a main outlet solenoid valve to an 8-outlet nurse, each equipped with an electronically controlled pulsed output solenoid valve; - An air purge system by the purge solenoid valve ensures the purity of the gas between two diffusion cycles by eliminating a possible remainder of pheromone trapped in the nurse and in the pipes, as well as rinsing the pipes. broadcast at the end of the cycle; Ambient factor sensors are arranged near the technical cabinet; 3034672 - 16 - o 8 polyethylene (PE) pipes with a diameter of 16mm and a length ranging from 80m for the shorter ones to 125m for the longest placed in the diagonal of the ground from the location of the technical cabinet , placed in a beam from the technical cabinet to cover all the ground of 1 ha. These pipes 5 are perforated and equipped with drippers every meter; the flow of drop driers. the basket of 130 g of a mixture of Codlemon®, dodecanol and tetradecanol is loaded at a ratio of 13: 7: 1.6, named pheromone, which is incorporated in 11.17 kg of cross-linked polyurethane granules, a total of 11.3 10 kg of polyurethane granules loaded with said pheromone; o The electric heater starts according to the preset program for the control of carpocapsea, then the air generator starts automatically. Air heating is programmed at 35 ° C; the treatment is carried out automatically, thanks to the light sensors, twice a day: 3 hours at dawn and 3 hours at dusk, ie 6 hours a day for 140 days; the polyurethane granules are recovered at the end of the season and analyzed for the gas chromatographic (GC) assay the pheromone remaining in the polymer.

The remaining amount of pheromone in the polymer is 97.5 g, which gives a consumption of 32.5 g / season / ha, a pheromone saving of 75%. The quantity of pheromone emitted per day by the system according to the invention is 232 mg / day / ha, ie 38.7 mg / h / ha as that emitted by the current systems. This result shows the desirability of the system according to the invention based on a targeted and optimized emission of the pheromone. EXAMPLE 2 It should be recalled that the sexual confusion treatment of walnuts against codling moth (Cydia pomonella) with the pheromone mixture composed of codlemone, dodecanol and tetradecanol is spread over a season of about 140 days. Currently to treat a plot of orchard of 1 hectare, is used 3034672 - 17 - hanging branches 500 diffusers marketed under the brand GINKO® (SumiAgro) with the following data: - the amount of pheromone actually used in each diffuser is 200 mg / season / ha; 5 - the amount of pheromone consumed in 1 season per hectare is 100 g / season / ha, ie 0.71 g / day / ha and 29.8 mg / h / ha. Application of the system according to the present invention The system of Example 1 is placed in a plot of walnut orchard of 1 ha, this time with the technical cabinet placed in the center of the plot. 10 18 pipes of diffusion of the pheromone mixture composed of Codlemon®, dodecanol and tetradecanol, are arranged in star around the technical cupboard. The pipes have a length varying between 4.5 m and 6.5 m. The polymer used is the same as that of Example 1, namely crosslinked polyurethane.

The diffusion of the pheromone is carried out according to the schedule of Example 1, namely twice a day: 3 hours at dawn and 3 hours at dusk, ie 6 hours per day for 140 days. The controlled insect is codling moth (Cydia pomonella). The pheromone did not diffuse during the evenings (twilights) and mornings (dawn) of heavy rains and / or high winds corresponding to a lack of activity for codling moth (Cydia pomonella). At the end of the 140-day season, it was found that pheromone consumption by the system according to the invention was 25 g / season / ha with an average consumption of 179 mg / day / ha, ie 30 mg / h / ha. The total consumption of the season of the system according to the invention is 24.7 g, ie 19% compared to that of the prior systems, which represents a saving of 105.3 g of pheromone compared to the current systems mentioned above. recall. This result demonstrates the desirability of the system according to the invention based on a targeted and optimized emission of the pheromone.

Claims (21)

CLAIMS1). Electronically assisted autonomous system for the targeted and optimized distribution by evaporation of semiochemical substances diffused at spatially separated locations and at specific times for the control of pests in specific areas of crops to be treated characterized in that it comprises: a) a gasification column (1) of at least one semiochemical substance, b) an air generator (2) connected to said gasification column (1) by a solenoid valve (2.1), C) at least one diffusion pipe ( 7) flexible fitted on the quick coupling of the solenoid valve (6.2), d) at least one ambient factor sensor, e) an electronic control module (9), f) an electric generator (8). 2). System according to Claim 1, characterized in that the said column (1) comprises: I. a gasification chamber (4) for heat-insulated semiochemical substances situated in the upper part of the said column (1) and equipped with a removable perforated container (5) carrying at least one semiochemical substance in solution or suspension incorporated into a granular or particle-shaped polymer matrix (5.1), or placed in liquid form in an open container; II. a cover (4.1) with heat-insulated wall closing the gasification chamber (4) from above; III. a heat chamber (3) of heat-insulated wall, located in the lower part of the column (1), in the extension of the gasification chamber (4) and provided with a heating element (3.3) and at least one temperature (3.1) and pressure (3.2) probe; IV. a nurse (6) with insulated wall, connected to the gasification chamber (4) by the main outlet electrovalve (6.1) and provided with several outlets each equipped with an outlet solenoid valve (6.2) ending with a quick coupling ; At least one air purge valve (6.3) for purging the nanny (6) and the diffusion pipes (7); 3). System according to one of Claims 1 and 2, characterized in that the electrical generator (8) is connected to all the electrical operating components of the system via an electronic power unit. 4). System according to one of claims 1 to 3 characterized in that the electric generator (8) is rechargeable battery by the public grid or solar panels. 5). System according to one of claims 1 to 4 characterized in that the electronic control module (9) is connected to all the organs providing the technical information and those to be controlled to ensure the automatic operation of the system. 6). System according to one of claims 1 to 5 characterized in that all of the components of said system, a) to f), is housed in a closed cabinet with orifices of diameter adapted to the outside diameter of the diffusion pipes. (7) coming out. 7). System according to Claim 1, characterized in that the duration and the moment of the emission are predetermined according to the physiology of the harmful insect to be controlled. 20 8). System according to Claim 1, characterized in that the sensors of the ambient factors collect the information concerning the luminosity, the temperature and the humidity of the air, as well as the presence and the force of the wind for the control of the emission at the moment. of said targeted semiochemical substance in the precise area to be treated. 25 9). System according to one of claims 1, 2 and 6 characterized in that only the outlet solenoid valves (6.2) of the pipes (7) serving an area to be treated at a given instant open automatically at said instant. 10). System according to one of Claims 1, 2, 6 and 9, characterized in that the outlet solenoid valves (6.2) operate in pulsed mode according to the principle of pulse width modulation (MU). 11). System according to one of claims 1, 2, 6, 9 and 10 characterized in that the diffusion pipes (7) have an internal diameter ranging between 15mm and 20mm, their length ranging between 40 m and 150 m according to the adopted configuration of distribution in the domain to be treated. 12). System according to claims 1, 2, 6, 9, 10 and 11 characterized in that the diffusion holes on the diffusion pipes (7) are of diameter varying between 0.2 5 mm and 2 mm. 13). System according to one of claims 1, 2, 6, 9, 10, 11 and 12 characterized in that said diffusion orifices are placed only on the segmental portions of the diffusion pipe (7) located in the zones only. infested to treat. 14). System according to one of the preceding claims, characterized in that the semiochemical substance is chosen from kairomones of natural origin or of synthetic origin. 15). System according to one of the preceding claims, characterized in that the insect / pheromone pairs are: - Cydia pomonella and Cydia fagiglandana and Cydia nigricana and Cydia splendana and Cydia strobilella and Cydia trasias E8-E10-dodecadiene-1-ol, 1- dodecanol, 1-tetradecanol; Cydia molesta: 8-dodecenyl acetate; Lobesia botrana and Eupoecilia ambiguella: Z9-dodecenylacetate, E7-Z9-dodecadienylacetate; 20 - Planococcus ficus: (S) - (+) - lavandulylsenecioate; Grapholita molesta: (Z) -8-dodecen-1-yl-acetate, (E) -8-dodecen-1-yl-acetate, (Z) -8-dodecen-1-ol; Keiferia lycopersicella: (E) -4-tridecenyl acetate; Pectinophora gossypiella (Z, E) -7,11-hexadecadienyl acetate, (Z, Z) -7,11-hexadecadienyl acetate; - Neodiprion sertifer 3,7-dimethyl-2-pentadeanol; - Amyelois transitella (Z, Z) -11,13-hexadecadienal, (Z, Z) -11,13-hexadecadien-1-ol, (Z, E) -11,13-hexadecadien-1-ol, (Z, Z, Z, Z, Z) - 3,6,9,12,15-tricosapentaene; - Ceratitis capitata: 3,4-dihydro-2h-pyrrole; Bactrocera oleae: 1,7-dioxaspiro [5.5] undecane; - Acrolepiopsis assectella: (Z) -11-hexadecenal, (Z) -11-hexadecenyl acetate, - Adoxophyes honmai and Adoxophyes orana and Adoxophyes orana fasciata and Adoxophyes reticulana (Z) -11-tetradecenyl acetate, (Z) -9-tetradecenyl acetate; - Agrotis segetum: (Z) -7-dodecenyl acetate, (Z) -9-tetradecenyl acetate, (Z) -5-dodecenyl acetate, (Z) -5-decenyl acetate; Anthonomus grandis: cis-2-isopropenyl-1-methylcyclobutaneethanol, (Z) -2- (3,3-dimethyl) -cyclohexylideneethanol, (E) - (3,3-dimethyl) -cyclohexylideneacetaldehyde, (E) -2- hexen-1-ol, (Z) - (3,3-dimethyl) cyclohexylidene acetaldehyde; 3034672 - 21 - - Aphis gossypii: E-beta-farnesene; - Archips argyrospila and Archips breviplicanus and Archips fuscocupreanus and Archips podana and Archips rosana and Busseola fusca: dodecyl acetate, (Z) -11-tetradecenyl acetate, (E) -11-tetradecenyl acetate, tetradecyl acetate, 5 (Z) -9- tetradecenyl acetate; Chilo suppressalis: (Z) -11-hexadecenal, (Z) -9-hexadecenal, (Z) -13-octadecenal; Diabrotica undecimpunctata howardi: 10-methyltridecan-2-one; - Diabrotica barber! and Diabrotica virgifera virgifera: 8-methyldecan-2-ylpropionate; - Diotyctria merkeli: (Z) -9-tetradecenyl acetate; Dioryctria amatella: (Z, Z, Z, Z, Z) -3,6,9,12,15-pentacosapentaene, (Z, E) -9,11-tetradecadienyl acetate; - Grapholita funebrana and Grapholita molesta and Grapholita prunivora: 15 (Z) -8-dodecenyl acetate, (E) -10-dodecenyl acetate, (E) -8-dodecenyl acetate; Heliothis maritime adaucta: (Z) -11-hexadecenal, (Z) -11-hexadecen-1-ol, hexadecanal; Heliothis virescens: (Z) -11-hexadecenal, (Z) -11-hexadecen-1-ol, (Z) -9-tetradecenal; Pandemis heparana and Pandemis limitata and Pandemis pyrusana: (Z) -11-tetradecenyl acetate, tetradecyl acetate, (Z) -9-tetradecenyl acetate, (Z) -11-tetradecen-1-ol, dodecyl acetate; Platynota flavedana and Platynota idaeusalis and Platynota stultana: tetradecyl acetate, (Z) -11-tetradecenyl acetate, (E) -11-tetradecenyl acetate, 25 (Z) -11-tetradecen-1-01, (E) -11- tetradecen-1-01, tetradecan-1-01; Orgyia leucostigma: (Z) -6-heneicosen-11-one, (Z) -6-heneicosen-11-one, (Z, Z) -6,9-heneicosadien-11-one, (Z, E) - 6,8-heneicosadien-11-one, (Z, E) -6,9-heneicosadien-11-one; Ostrinia fumacalis: (E) -12-tetradecenyl acetate, (Z) -12-tetradecenyl acetate, tetradecyl acetate; Ostrinia nubilalis: (Z) -11-tetradecenyl acetate, (E) -11-tetradecenyl acetate; - Tetranychus urticae: (E, Z) -3,7,11-trimethyl-2,6,10-dodecatrien-1-ol, (Z) -3,7,11-trimethyl-1, 6, 10-dodecatrien- 3-ol, 3,7-dimethyl-6-octen-1-ol, (E) -3,7-dimethyl-2,6-octadien-1-01; Tuta absoluta: (E, Z, Z) -3,8,11-tetradecatrienyl acetate; - Synanthedon exitiosa and Synanthedon pictipes and Synanthedon myopaeformis and Synanthedon scitula and Synanthedon tipuliformis: (Z, Z) -3,13-octadecadienyl acetate, (E, Z) -3,13-octadecadienyl acetate, (Z, E) -3, 13-octadecadienyl acetate; Rhyacionia frustrana and Rhyacionia zozana and Rhyacionia buoliana (E) -9-dodecen-1-ol, (E) -9,11-dodecadienyl acetate, (E) -9-dodecenyl acetate; Spodoptera exigua (Z) -11-hexadecenyl acetate, (Z) -9-tetradecen-1-ol, (Z, E) -9,12-tetradecadienyl acetate; - Spodoptera frugiperda (Z) -7-dodecenyl acetate, (E) -7-dodecenyl acetate, (Z) -9-tetradecenyl acetate; Spodoptera littoralis (Z, E) -9,12-tetradecadienyl acetate, (Z, E) -9,11-tetradecadienyl acetate. 3034672 - 22 - 16). System according to one of the preceding claims characterized in that the polymer is of natural origin, synthetic, biosourced or a mixture thereof, biodegradable or not. 17). System according to one of the preceding claims, characterized in that the polymers of natural origin are chosen from protein polymers, lignocellulosic polymers, protein-cellulosic polymers or cellulosic polymers and their derivatives. 18). System according to one of the preceding claims, characterized in that the polymers of natural origin are derived from agro-industrial by-products selected from sunflower, soya or grape seed cake, as well as coffee grounds. , wheat bran, reduced corn cob, porosified cereal grains, reduced cork, as well as wheat and maize flours processed and shaped into pellets. 19). System according to one of the preceding claims, characterized in that the polymers of synthetic origin are chosen from the absorbent grades of polyolefins, polyamide and its derivatives, polyethylene and its derivatives, polyurethane, polyvinyl chloride and acrylates. or polyesters, as well as copolymers and combinations thereof. 20). System according to one of the preceding claims, characterized in that the content of semiochemical substance incorporated in the polymer matrix varies between 5% and 40% by weight. 21). A method for controlling pests at spatially different locations at the same time in the crop fields using the electronically assisted autonomous system according to claim 1, characterized in that said system is installed either in the middle or in the periphery of the fields to be treated so that the diffusion pipes (7) are arranged in radiating formation towards the locations corresponding only to the zones to be treated. 30