• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
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    • 专利摘要:
    The invention relates to an apparatus for trapping harmful flying insects comprising: - a device for diffusing (1) an attractive gaseous cocktail whose composition is adapted to attract insects, - a suction device (2) exhibiting a suction orifice (220) for an air flow containing the insects attracted by the diffused attractant cocktail; - a trap arranged with the suction device (2); - a frame (4) enclosing a source of gas; , which gas is a component of the attractive gaseous cocktail, characterized in that the diffusion device (1), the suction device (2) and the insect trap form a structure (S) connected to the frame (4) by means of at least one means for adjusting the height of said structure, in the sense of spacing or approximation of the ground level of the suction port (220).
    公开号:FR3078608A1
    申请号:FR1851929
    申请日:2018-03-06
    公开日:2019-09-13
    发明作者:Pierre BELLAGAMBI;Simon LILLAMAND
    申请人:Techno Bam;
    IPC主号:
    专利说明:

    The subject of the invention is an apparatus and a method for trapping harmful flying insects.
    It concerns the technical field of systems making it possible to attract and capture harmful flying insects, in particular nematocerous dipterous insects (blood suckers) and haematophagous dipterans (biters).
    State of the art.
    In areas particularly exposed to the presence of mosquitoes, communities, tourist offices and individuals spend considerable sums to carry out preventive treatments to destroy mosquito larvae.
    Various mosquito control techniques currently exist:
    - the larvicidal technique: it involves the use of chemical or biological products which act on mosquitoes in the immature stage to slow down their development. This technique is effective in slowing the development of mosquitoes, because their larvae generally occupy a minimum geographic space and easily located. However, it is very expensive. Moreover,
    -2the frequent use of larvicides can lead to habituation and resistance to the product used.
    - the insecticide technique: it aims to eliminate adult mosquitoes with synthetic or natural chemical substances (eg pyretroids). However, this technique generates considerable costs and involves heavy logistics (aerial or ground spraying). In addition, insecticidal substances can also have harmful effects on human and animal health. In addition, their repeated use presents a risk of resistance.
    - the repellents technique: it aims to divert mosquitoes from their potential target, by disrupting their ability to spot with synthetic or natural chemicals (for example DEET (N, N-diethyl-3methylbenzamide). However, this technique does not mosquitoes do not usually kill mosquitoes, but repel them, and few long-term toxicity studies have been performed on the repellents currently available on the market.
    Environmental studies show that all chemicals degrade badly and tend to diffuse into the ecosystem. In addition to being harmful to the fauna of the treated areas by impacting the base of the food chain, mosquito control only treats wild areas without treating urbanized areas where nuisances are essential and where the risks of proliferation of viral infection linked to mosquitoes are the largest. The chemicals used reach and destroy the natural predators of mosquitoes, which significantly reduces the overall effectiveness of mosquito control campaigns.
    The protection of living areas located in regions infected by mosquitoes therefore requires finding environmentally less aggressive means.
    -We know by patent documents WO2016 / 020627 (TECHNO BAM), US 2009/0162253 (PORCHIA), US 2007/0006520 (DURAND), US 2004/0154213 (MOSHER) or US 5813166 (WIGTON), devices capable of providing an adapted alternative response, corresponding to a real need. These devices generally include: - a device for diffusing, into the surrounding ambient air, an attractive gaseous cocktail whose composition is adapted to attract insects; - a suction device having a suction opening of a surrounding ambient air flow containing the insects attracted by the gaseous attractant cocktail diffused; - an insect trap arranged with the suction device so that the insects sucked by said device are retained in said trap; - a frame containing a gas source connected to the diffusion device, which gas is a constituent of the attractive gas cocktail. This type of device is an alternative to mosquito control by larvicide.
    These prior art devices can generally only trap a small number of harmful flying insect species. Indeed, the different species of flying insect pests do not all fly at the same height. Some fly very close to the ground such as the tropical Aedes Alobopictus, Aegypti or Anopheles mosquitoes, and others fly away from the ground such as bird mosquitoes. In the aforementioned devices, the suction device is generally secured to the frame containing the gas source, so that the suction port is located at a fixed distance from the ground. These devices therefore have limited effectiveness when installed in areas where insects fly close to the ground.
    Patent document EP 1,049,373 (AMERICAN BIOPHYSICS CORP) suggests positioning the suction port at a distance from the ground of between 1 foot and 3 feet to capture species flying close to the ground. A hook allows the device to be suspended at a height, to catch other species, for example certain tropical species which fly in the canopy. Height adjustment
    -4de the suction port of this device is relatively rudimentary, imprecise and inconvenient for the user.
    The invention aims to remedy this state of affairs. In particular, an objective of the invention is to provide a device whose efficiency is optimal regardless of the area where it is installed.
    Another object of the invention to provide a device which is convenient for the user, simple in design, inexpensive, easy to use, and easily manipulated.
    Disclosure of the invention.
    The solution proposed by the invention is an apparatus for trapping harmful flying insects comprising:
    - a device for diffusing, into the surrounding ambient air, an attractive gaseous cocktail, the composition of which is adapted to attract insects,
    - a suction device having a suction opening for a surrounding ambient air flow containing the insects attracted by the attracting gaseous attractant cocktail,
    - an insect trap arranged with the suction device so that the insects sucked by said device are retained in said trap,
    - a frame containing a gas source connected to the diffusion device, which gas is a constituent of the attractive gas cocktail.
    This device is remarkable in that the diffusion device, the suction device and the insect trap form a structure connected to the chassis by means of at least one means for adjusting the height of said structure, in the direction of '' a spacing or approximation of the ground level of the suction orifice.
    -5When the user installs the device in an area to be treated, and has determined the species or species of harmful flying insects to be trapped, it suffices to adjust the height of the structure, in the direction of '' a spacing or approximation of the ground level of the suction orifice. If the species to be treated fly close to the ground, the adjustment will be made in a direction of bringing the ground level closer to the suction port. On the contrary, if the species to be treated fly away from the ground, the adjustment will be made in a direction away from the ground level of the suction port. The device object of the invention can therefore be considered universal insofar as it works optimally in any geographical area and regardless of the harmful flying insect species to be trapped.
    Other advantageous features of the invention are listed below. Each of these characteristics can be considered alone or in combination with the remarkable characteristics defined above, and be the subject, if necessary, of one or more divisional patent applications:
    - Advantageously, the height adjustment means is in the form of at least one crossmember fixed to the structure, which crossmembers is fixed to the chassis in a plurality of vertical positions making it possible to adjust the spacing or the approximation of the ground level the suction port.
    According to an alternative embodiment, the height adjustment means is in the form of at least one cross-member fixed to the chassis, which cross-member is joined to the structure according to a plurality of vertical positions making it possible to adjust the spacing or the approximation of the ground level of the suction opening.
    Advantageously, a fluid connection is made between the gas source installed in the chassis and the diffusion device, which fluid connection passes through the at least one cross member.
    - An electrical power source can be installed in the chassis, an electrical connection being made between said source and the structure, which electrical connection passes through the at least one cross member.
    - The chassis can be in the form of an urban lamp post.
    Advantageously, an optical insect counter is placed at the level of the suction opening.
    Advantageously, the suction device comprises a heating element (240) disposed at the level of the suction orifice, upstream of said orifice.
    - This heating element is preferably heated to a temperature between 35 ° C and 45 ° C.
    Advantageously, the diffusion device is controlled by a control unit adapted so that the attractive gaseous cocktail is diffused into the surrounding ambient air according to a sinusoidal rhythm simulating a respiration rate of a human being.
    - This control unit is preferably adapted to vary the frequency of the sinusoidal rhythm of diffusion of the gaseous attractant cocktail.
    Another aspect of the invention relates to a method for trapping harmful flying insects comprising:
    - diffuse, in the surrounding ambient air, an attractive gaseous cocktail whose composition is adapted to attract insects,
    - suck, through a suction opening, a surrounding ambient air flow containing the insects attracted by the attractant gaseous cocktail diffused,
    - keep the sucked insects in a trap.
    the method further comprising the steps of:
    - use a device conforming to one of the preceding characteristics,
    - identify at least one species of harmful flying insects to be trapped,
    - adjust the height of the structure of the device, in the direction of spacing or approximation of the ground level of the suction port, which adjustment is made according to the identified species of insect harmful flywheels.
    Description of the figures.
    Other advantages and characteristics of the invention will appear better on reading the description of a preferred embodiment which will follow, with reference to the appended drawings, produced by way of indicative and nonlimiting examples and in which:
    - Figure 1 is a perspective view of an apparatus according to the invention,
    - Figure 2 shows the apparatus of Figure 1 with the partially disassembled diffusion device,
    FIG. 3a is a perspective view of a foldable plate constituting the diffusion device,
    FIG. 3b is a perspective view of the diffusion device obtained by folding the plate of FIG. 3a,
    FIG. 4a is a perspective view of a foldable plate constituting the suction device,
    - Figure 4b is a perspective view of the suction device obtained by folding the plate of Figure 4b,
    FIG. 5a is a perspective view of a foldable plate constituting the chassis containing the gas source,
    FIG. 5b is a perspective view of the chassis obtained by folding the plate of FIG. 5b,
    FIG. 6a is an enlarged view of the suction opening associated with an optical insect counter,
    FIG. 6b schematically illustrates, seen from above, the arrangement of an optical insect counter at the level of the suction orifice,
    - Figure 7 is a schematic sectional view of an apparatus according to the invention;
    - Figure 8 shows an apparatus according to the invention according to an alternative embodiment,
    FIG. 9 is a diagram illustrating different sinusoidal rhythms of diffusion of the gaseous attractant cocktail in the surrounding ambient air,
    - Figure 10 shows schematically a configuration of the fluid connection and the electrical connection at a cross member,
    - Figure 11 illustrates an installation comprising several devices according to the invention networked.
    Preferred embodiments of the invention.
    The device which is the subject of the invention is intended to trap nematocerous dipterous insects (blood suckers) such as mosquitoes and hematophagous dipterous insects (biters of their prey) such as black flies. The principle consists in simulating the presence and the respiration of a mammal in its place. More generally, the invention aims to trap harmful flying insects. Attracted by an attractive cocktail, the targeted insects are then sucked in and captured. Thus imprisoned, the insects can be either killed or recovered alive, for example for a later scientific study.
    In FIGS. 1 and 2, the apparatus A comprises:
    a diffusion device 1, making it possible to diffuse into the surrounding ambient air, a gaseous attractive cocktail whose composition is adapted to attract insects,
    a suction device 2 having a suction orifice 20 for a surrounding ambient air flow containing the insects attracted by the attractive gaseous cocktail diffused by the diffusion device 1,
    - An insect trap 3 arranged with the suction device 2 so that the insects sucked by said device are retained in said trap, a frame 4 containing a source of gas connected to the diffusion device 1, which gas is a constituent of the attractive gaseous cocktail. The chassis 4 is placed directly on the ground and can be provided with wheels so as to make it mobile and / or displaceable.
    In FIG. 2, the diffusion device 1 comprises a hollow parallelepiped box 10 fixed on a plate 11 forming a cap. For example, the box 10 has a height between 10 cm and 20 cm and sides whose length is between 10 cm and 20 cm. The attachment of the box 10 to the plate 11 is preferably carried out by magnetization so that a user can easily separate these two elements. Fixing by screwing or snapping is also possible. The plate 11 is in the form of a horizontal flat plate of square shape, made of steel or plastic, and in particular a plastic material of the expanded polypropylene type, preferably marketed under the brand FOAMLITE®. The sides of the tray 11 have dimensions greater than the sides of the box 10. For example, the sides of the tray 11 are twice as long as those of the box 10.
    In FIGS. 3a and 3b, the box 10 is shaped from a plate 100 comprising side panels 100a, 100b, 100c, 100d linked together by folds 101 allowing it to be placed in volume. Maintaining the shape of the box 10 is ensured by fixing by gluing, welding or by interlocking the lateral edges of the end panels 100a and 100d. A cover 110 closes the upper part of the box 10 after the latter has been placed in volume. The cover 110 is advantageously removable so as to allow easy access to the interior of the box 10.
    The use of such a plate 100 has several advantages and in particular: a simple volume setting and requiring no specific tools; a reduced size which is particularly appreciable during the transport and / or storage phases before being placed in volume.
    The plate 100 and the cover 110 are preferably made of plastic material of the expanded polypropylene type, preferably marketed under the brand FOAMLITE®. This material has indeed, in addition to
    - Its low weight, good mechanical resistance and good resistance to chemical attack.
    Each panel 100a-100d of the plate 100 has, on its internal face (ie the face located inside the box 10 after the latter has been put into volume), a longitudinal groove 102 in which is housed, without other type fixing means, the edges of a support plate as explained further in the description.
    Once set in volume and closed by the cover 110, the box 10 defines a hollow chamber 15 inside which are installed the elements making it possible to dispense the attractive gaseous cocktail. The latter is preferably a mixture of CO2 and volatile olfactory lures. CO2 induces nerve stimulation similar to that produced by the respiration of a warm-blooded mammal. The scent lures used advantageously reproduce the smell of human skin. For example, octenol (CsH-ieO), in particular 1-octen-3-ol (CAS # 3391-86-4), and / or lactic acid are used, these compounds giving good results. These compounds also avoid attracting non-harmful flying insects such as bees.
    Referring more particularly to FIG. 7, the olfactory decoys are arranged in a removable cartridge 9, which cartridge is placed in the hollow chamber 15, above a fan 6. The cartridge 9 is installed on the upper face of the support plate 90 which fits into the longitudinal grooves 102 mentioned above. The fan 6 is installed on the underside of this support plate 90. The latter thus divides the hollow chamber 15 into two zones: an upper zone in which the cartridge 9 is installed and a lower zone in which the fan 6 is installed. plate 90 has orifices or arrangements allowing air circulation from the lower zone to the upper zone of the hollow chamber 15.
    The scent lures are advantageously contained or impregnated in a lure support which is placed in the air flow Fb generated in the hollow chamber 15, by the fan 6. This lure support is preferably chosen from (i) a candle; (ii) a porous support such as wooden balls, exploiting the capillary effect; (iii) a support in the form of a gel; and (iv) a plate of more or less spongy absorbent material. Good results are obtained when the lure support is porous and when the olfactory lures are used in the liquid state.
    In FIG. 7, the chassis 4 contains a source 41 of CO2. The latter is for example in the form of a refillable pressure cylinder, the capacity of which is for example between 0.5 kg and 50 kg. A flexible pipe 42 puts the cylinder 41 and the hollow chamber 15 in fluid communication, and more particularly the lower zone of said chamber where the fan 6 is contained. The CO2 is in fact mixed with the air flow sucked in by the fan 6 and with the volatile olfactory decoys placed in the cartridge 9. A flow meter 43 makes it possible to adjust the CO2 flow injected into chamber 15. Very good results are obtained when this flow is between 0.15 L / min and 0.5 L / min. According to an advantageous characteristic of the invention, the CO2 is diffused continuously in the hollow chamber 15. Even when the fan 6 is inactive, the CO2 diffuses into the tank 51 by passing through the blades of said fan. The cylinder 41 can be associated with a sensor making it possible to warn an operator when said cylinder is empty.
    Insects are all the more attracted to CO2 because its temperature is higher than the temperature of the surrounding ambient air. It may therefore be advantageous to heat the CO2 beforehand before its diffusion. This heating can be naturally induced by the incident rays of the sun which heat the hollow chamber 15. To amplify this natural phenomenon, the hollow chamber 15 can be formed by, or contain, a refractory material (steel plates, lava stone, ...) suitable for storing heat and returning it to the Fb flow, and therefore to CO2.
    As the air flow Fb generated by the fan 6 and charged with CO2 passes, the olfactory decoys contained in the cartridge 9 evaporate. However, they diffuse continuously in the hollow chamber 15, even in the absence of the air flow generated by the fan 6. This is essentially due to the fact that the hollow chamber 15 is heated by the incident rays of the sun, the temperature prevailing inside the box 10 causing continuous evaporation of the olfactory decoys inside said chamber. When the cartridge 9 is empty, it suffices to remove the cover 110 to remove it and replace it with another. The cartridge 9 can be associated with a sensor making it possible to warn an operator when it is empty.
    The fan 6 is advantageously adapted to expire the flow Fb at a flow rate between 10 m 3 / H and 300 m 3 / H, preferably around 150 m 3 / H. It draws in ambient air from orifices 130 produced on the panels 100a-100d of the plate 100 (FIGS. 3a, 3b and 7), under the plate 90, in the lower zone of the hollow chamber 15. The air flow sucked in by the fan 6 is discharged into the upper zone of the hollow chamber 15, from which it emerges through orifices 140 produced on the panels 100a-100d of the plate 100 (FIGS. 3a, 3b and 7), above the plate 90 The orifices 130 and 140 open out to the surrounding ambient air and are arranged homogeneously or not around the periphery of the box 10. The gaseous attractive cocktail can thus spread over a large area, in particular over a range of action. from around 50 m to 60 m, corresponding to an area of around 10,000 m 2 .
    In practice, the fan 6 comprises a motor which draws a sign of electrical power from a battery to rotate its blades, thereby generating the flow Fb. The fan 6 is controlled by a control unit 60 (FIG. 7)
    - 13 present for example in the form of an electronic card incorporating a processor and / or a time delay.
    The inventors have found that the number of trapped insects increases when the attractive gaseous cocktail is released into the surrounding ambient air in a sinusoidal rhythm simulating a human respiration rate. Also, the control unit 60 is configured to drive the fan 6 so that the flow Fb that it generates is according to this sinusoidal rhythm. The frequency (number of cycles or periods per unit of time) of the sinusoidal rhythm of diffusion of the attractive gaseous cocktail can vary over the course of a day in order to simulate an increase in the rate of breathing linked to a sporting activity, or a decrease to simulate a rest period. This frequency is preferably between 10 cycles per minute and 70 cycles per minute.
    FIG. 9 is a diagram illustrating different sinusoidal rhythms of diffusion of the gaseous attractant cocktail in the surrounding ambient air. The abscissae correspond to time (t) and the ordinates correspond to the flow rate of the flow Fb (Q Fb ) exhaled out of the box 10. Three sequences R1, R2 and R3 are shown. The sequence R1 simulates a respiratory rhythm of an adult human being, for example between 20 to 40 cycles per minute. The R2 sequence simulates a respiratory rhythm of an adult human being at rest, for example between 10 to 20 cycles per minute. The sequence R3 simulates a respiratory rhythm of an adult human being during sporting activity, for example between 40 to 60 cycles per minute. In this figure 9, the amplitude is the same for each sequence. It can however vary from one sequence to another, or even during the same sequence.
    The suction device 2 and the insect trap 3 will now be described in more detail. In FIGS. 1 and 2, the suction device 2 is located below the diffusion device 1. With reference to FIGS. 4a and 4b, the suction device 2 comprises a hollow parallelepiped box 20 having, at
    - 14title of example, a height between 30 cm and 60 cm and sides whose length is between 10 cm and 20 cm. In FIGS. 4a and 4b, the box 20 is shaped from a plate 200 comprising side panels 200a, 200b, 200c, 200d linked together by folds 201 allowing it to be placed in volume. Maintaining the shape of the box 20 is ensured by fixing by gluing, welding or by interlocking the lateral edges of the end panels 200a and 200d. The plate 200 is also associated with a cover 210 which closes the upper part of the box 20 after the latter has been placed in volume. This cover 210 has a circular opening 220 forming a suction opening and whose diameter is for example between 8 cm and 18 cm.
    The plate 200 is preferably made of plastic material of the expanded polypropylene type, preferably sold under the brand FOAMLITE®. The use of such a plate 200 has the same advantages in terms of weight, simplicity of assembly and reduced bulk as those mentioned previously with reference to the plate 100.
    Once placed in volume, the box 20 defines a hollow chamber 25 inside which the insect trap 3 is installed. In FIGS. 1 and 2, a hatch and / or a door 250 mounted movably between a closed position ( Figure 1) and an open position (Figure 2) is advantageously provided to allow access to the interior of the hollow chamber 25. In the accompanying figures, this door 250 is mounted movable in vertical translation. It could, however, have a rotational movement around a hinge.
    Referring to Figure 7, the suction port 220 opens into this insect trap 3, which trap is in the form of a flexible mesh bag, or net. It is attached, for example by means of a cord or clamp at the suction port 220. This net 3 is advantageously reusable, and can perhaps be recovered and changed from the door 250 .. The net 3 can be combined with a sensor to indicate its filling.
    - In Figure 7, the suction device 2 comprises a suction means 23, preferably in the form of a fan. This suction means 23 is suitable for sucking in ambient air at a flow rate of between 15 m 3 / h and 500 m 3 / h, preferably around 350 m 3 / h. The flow rates Fa and Fb are advantageously different. In fact, the inventors have found that more insects were captured when the flow Fa aspirated was greater than the flow Fb exhaled.
    The fan 23 creates a depression in the box 20 and sucks the surrounding ambient air through the suction orifice 220, through the thread 3. The flow of aspirated ambient air is shown diagrammatically by the arrow referenced Fa in FIG. 7 In practice, the fan 23 comprises a motor which draws an electrical power signal from a battery to rotate its blades, thereby generating the flow Fa. The fan 23 is coupled to a control member 230 making it possible to control its operation.
    In FIGS. 1, 2 and 7, the diffusion device 1 is located above the suction device 2 and the trap 3. The plate 11 has several functions: it protects the suction orifice 220 from the weather, preventing in particular the rainwater to penetrate inside the box 20 and the trap 3; it also forms a physical barrier which prevents the exhaled Fb flow charged with an attractive gaseous cocktail from being taken up by the aspirated air flow Fa.
    According to an advantageous characteristic of the invention illustrated in Figures 6a and 6b, the suction device 2 is provided with an optical insect counter disposed at the suction port 220. This counter comprises a series of parallel deflectors 30 installed across the suction opening 220. These deflectors 30 are for example made of steel or plastic and are spaced from one another by a distance of between 4 mm and 9 mm.
    In each interval between the deflectors 30 (or space separating two successive deflectors), a light barrier is installed composed of a light emitter 31 and a light receiver 32. The emitter 31 is arranged
    - 16 at one end of the interval and the receiver 32, opposite, that is to say at the other end of said interval. The transmitter 31 is preferably an infrared LED. And the receiver 32 is preferably a photodiode. The suction port 220 is thus "blocked" by a series of light barriers. The deflectors 30 have the function of distributing and channeling the insects towards these light barriers. When an insect passes between the transmitter 31 and the receiver 32, the latter is not lit. It is in a non-conductive state. When there is no insect which cuts the light barrier, the receiver 32 is directly lit by the transmitter 31 and is in a conductive state. These two states are interpreted by a microcontroller by two binary states 0 or 1, which makes it possible to count the number of insects.
    The meter is advantageously located as close as possible to the suction port 220, at the start of the suction zone. Indeed, at this point the insect has a minimum fall and aspiration distance, reducing the speed of passage in front of the light barriers, making the count more precise. This performance also makes it possible not to excessively increase the sensitivity of the receiver 32, which avoids counting other particles (for example dust) capable of being sucked up by the suction device 2.
    Referring to Figures 5a and 5b, the frame 4 comprises a hollow rectangular box 40 having, for example, a height between 60 cm and 150 cm and sides whose length is between 20 cm and 40 cm. The box 40 is shaped from a plate 400 comprising side panels 400a, 400b, 400c, 400d connected together by folds 401 allowing it to be placed in volume. Maintaining the shape of the box 40 is ensured by fixing by gluing, welding or by interlocking the lateral edges of the end panels 400a and 400d. The box 40 is closed at its upper part by a cover 410 and at its lower part by a bottom plate 411. The cover 410 is advantageously removable so as to allow easy access to the interior of the box 40 .
    Once set in volume, the box 40 defines a hollow chamber 45 inside which is installed the gas source 41 and an electric power source 46, for example of the battery type, adapted to supply electricity to the various components of the device A and in particular the various electronic components 60, 230, 30 and the actuators 6, 23. The battery 46 can be coupled to one or more solar panels and / or wind turbines so as to make the device A autonomous. The battery 46 can also be recharged simply by connecting it to a power supply of the mains type. In general, the electric power source 46 can be coupled to a time delay set so as to deactivate the device A during periods when the insects are not very active, for example from midnight to 4 am.
    In the alternative embodiment illustrated in Figure 8, the frame 4 is in the form of an urban lamp post. In this case, the gas source 41 is directly integrated inside the structure of the lamppost. The electrical power source may consist of a battery integrated in the structure of the lamppost and / or in the electricity distribution network and / or a photovoltaic panel P and / or a wind turbine installed on the structure of said lamppost. The device A can for example operate, during the periods of lighting, thanks to the electricity distribution network, and outside these periods, thanks to the battery, the latter being adapted to recharge during the periods of lighting.
    The operation of the apparatus A as well as the capture technique will now be described in more detail. All or part of the attractive gas cocktail is dispensed inside the hollow chamber 15. This attractive gas cocktail is then expelled at a sinusoidal rhythm into the surrounding ambient air as explained previously with reference to FIG. 9. At least the lures Olfactory contained in the cartridge 9, and preferably the CO2, are dispensed continuously inside the hollow chamber 15. The latter is therefore loaded with an attractive gaseous cocktail. The inventors have been able to demonstrate that a rate of expulsion of olfactory lures of between 0.03 ml / day and 0.3 ml / day contributes to improving
    - 18the attractive properties of the attractive cocktail. When the fan 6 is activated, the air flow Fb which it generates, charged with CO2, mixes intimately with the olfactory decoys concentrated in the upper zone of the hollow chamber 15, the gaseous attractive cocktail then being expelled from said chamber through ports 140.
    The inventors have surprisingly found that the attractive properties of this mixture, perfectly homogenized and expelled according to a sinusoidal rhythm, were clearly improved compared to the attractive cocktails diffused according to the techniques described in the aforementioned patent applications, and in particular according to a rhythm sequence. The sinusoidal rhythm of these exhalations optimally excites the sensors of all the Diptera and thus also makes it possible to capture the hematophages. Insects, attracted by this stimulus, instinctively seek to reach the area where the attractive cocktail has maximum concentration, i.e. the hollow chamber 15.
    Arrived near the source of the attractive cocktail, the insects head towards the chamber 15. The fan 23 creates a continuous depression at the suction orifice 220 and generates the air flow Fa. When, to reach the chamber 15, the insects fly near the suction orifice 220, they are sucked into the air flow Fa then retained in the trap 3.
    The inventors have also found that certain biting insects such as tropical mosquitoes may find it difficult to finalize their race towards the suction port 220. Also, to further improve the attraction of these insects, the suction device 2 advantageously comprises a heating element disposed at the suction port 220, which element simulates body heat. In Figure 7, the heating element 240 is located above the suction port 220, upstream thereof. This heating element 240 can be in the form of an electric heating resistance. It is preferably heated to a temperature between 35 ° C and 45 ° C. This heating point allows biting or biting insects to visualize a simulated body area that can facilitate their stings or bites. The insects are then guided to a no return zone where the suction of the Fa flow will be more
    - 19high as their flight capacity, so that they are sucked in through port 220 and captured.
    As illustrated in the appended figures, the diffusion device 1, the suction device 2 and the trap 3 form a structure S secured to the chassis 4. This structure S is distant from the chassis 4 and spaced laterally from the latter.
    The connection between the structure S and the chassis 4 is made of at least one means for adjusting the height of said structure in the direction of a spacing or a bringing together of the ground level of the suction orifice 220. This possibility of height adjustment allows the user to modulate the configuration of the device A as a function of the species or flying insects harmful to trap which he will have previously identified. It can thus optimally adjust the height of the suction opening 220 depending on whether the species to be treated that it has identified are flying close to or at a distance from the ground, thereby effectively improving the efficiency of the device. A in terms of trapping.
    Good results for treating most of the harmful insect flying species are obtained when the distance "D" between the ground and the suction port 220 varies from 40 cm to 1 m. Satisfactory results are also obtained by providing three different height adjustment positions: a low position where “D” is approximately equal to 50 cm; an intermediate position where "D" is approximately equal to 65 cm; and a high position where “D” is approximately equal to 80 cm. This modularity is particularly effective for tropical mosquitoes of the Aedes Alobopictus, Aegypti and Anopheles type which fly close to the ground and seek to bite their prey on the lower parts of the body.
    According to a first embodiment illustrated in particular in Figures 1,2 and 7, the height adjustment means is in the form of at least one, preferably two cross-members 5 fixed to the structure S and more particularly fixed to the box 20 forming the suction device 2. In this embodiment, there is no relative movement between the crosspieces 5 and the box 20.
    The crosspieces 5 are in the form of rigid parallel sections, arranged horizontally or, in other words, normal to the walls of the boxes 20 and 40. Their section can be square, rectangular, round, oval, or the like, and they are advantageously made of steel or plastic. Their length is for example between 10 cm and 30 cm so that the structure S is substantially distant from the chassis 4 of this same length. Each cross-member 5 can be produced in a single piece obtained by extrusion, molding or machining, or in two pieces assembled together according to the median plane of said cross-member. The fixing of the cross-member 5 on the wall of the box 20 is done at the distal end of said cross-member, by screwing, bolting, snap-fastening or by means of a flange.
    Each cross member 5 is secured to the chassis 4 according to a plurality of vertical positions making it possible to adjust the spacing or the approximation of the ground level of the suction orifice 220. These different vertical positions are materialized by recesses or housings 50 made in at least one wall of the box 40 forming the frame 4. These recesses or housings 50 are preferably through and have a section which corresponds to that of the crosspieces 5. The proximal end of the crosspieces 5 is thus housed by nesting in a recess or housing 50. Maintaining the position of the crosspieces 5 in the recesses or housings 50 can be ensured by a solution by screwing, bolting or snapping the proximal end of said crosspieces into the wall of the box 40.
    The recesses or housings 50 are arranged in a column and are four in number in the appended figures. Their number can however vary from 2 to 10 depending on the number of crosspieces 5 used and / or the desired height adjustment.
    In an alternative embodiment, the height is adjusted at the level of the structure S. The cross member (s) 5 are here fixed to the frame 4 and more particularly to the box 40, without relative movement between said cross members and said box. Each cross-member 5 is joined to the structure S according to a plurality of vertical positions making it possible to adjust the spacing or the approximation of the ground level of the suction orifice 220. The recesses or housings 50 described above are thus produced in at least a wall of the box 20 forming the suction device 2 so that the distal end of a cross-member 5 is received by fitting into one of said recesses according to the height adjustment position chosen.
    According to an advantageous characteristic of the invention, a fluid connection between the gas source 41 and the diffusion device 1 passes through at least one cross member 5. Similarly, an electrical connection between the electrical power source 42 and the structure S passes through at least one cross-member 5. The fluid connection and the electrical connection can pass through the same cross-member 5 or in separate cross-members.
    The cross-member 5 thus offers physical protection to these connections. In addition, the fact that the cross-member 5 acts as a support for these connections facilitates the modularity of the device A when adjusting the height of the suction orifice 220, in particular the connection and supply of gas and electricity from the attractive and aspiring part (structure S) to the technical part (chassis 4).
    To simplify the design, the cross-member 5 has a hollow conduit opening at its two ends and in which the fluid and electrical connections are housed. More particularly, their distal end opens into the hollow chamber 25 of the box 20 and their proximal end opens into the hollow chamber 45 of the box 40.
    In FIG. 7, the pipe 42 connected to the cylinder 41 runs inside the cross-member 5, passes into the hollow chamber 25 of the box 20 and opens into the lower zone of the chamber 15 of the diffusion device 1. Also , an electric cable 460 connected to the battery 46 runs inside the same cross-member 5 and opens into the hollow chamber 25 so as to be able to supply the various electronic components 60, 230, 30 and the actuators 6, 23 contained in the structure S. The fluid and electrical connection between the chassis 4 and the structure S is thus made very simply and completely secure, which are perfectly protected and made inaccessible.
    When the user varies the height of the structure S, he is required to disengage the crosspieces 5 of recesses or housings 50 in order to reposition them in other recesses or housings. To facilitate this manipulation, it appears advantageous to provide removable connectors for the pipe 42 and the electric cable 460. Referring to FIG. 10, the pipe 42 is provided with a removable connector 420 of the quick coupling type and the electric cable. 460 of a removable electrical connector 4600 of the male-female plug type. These connectors 420, 4600 are located at the proximal end of the crossmember 5 and accessible from inside the chamber 45 of the chassis 4.
    Thus, to modify the position of the crosspieces 5, the user just has to: disconnect the connectors 420, 4600; disengage the crossmember 5 from the recess or housing in which it is fitted; reposition the crosspiece 5 in another recess or housing; and finally reconnect the 420, 4600 connectors.
    In FIGS. 1 and 2, the diffusion device 1 is kept at a distance from the suction orifice 220 by means of spacers 12. The latter preferably consist of hollow tubes whose length is for example between 2 cm and 15 cm and which are fixed on the one hand on the cover 210 of the box 20 and on the other hand to the plate 11, around the suction port 220. To supply gas and electricity to the diffusion device 1, it can be seen in FIG. 7 that the pipe 42 and the electrical cable 460 pass through these spacers 12 so that the fluidic and electrical connections between the box 20 and the diffusion device 1 are perfectly protected and made inaccessible.
    By placing a plurality of these devices A at judiciously chosen locations, it is possible to form a protective belt around a small urban community or even an open public space, thus making it possible to protect them from nuisances due to the target harmful insects. Of course, the CO2 supply can be specific to each device A or be common to several devices.
    Device 23 (or each of the devices) advantageously includes an electronic card adapted to ensure its autonomous or programmed operation. This electronic card can for example:
    control the operating ranges of device A (or each of the devices);
    and / or switch the electrical supply of the device between the battery 46 and an electrical distribution network;
    and / or receive an electronic signal including atmospheric data relating to the environment in which the device A is located; process this electronic signal; and order the interruption of the operation of the apparatus A when the electronic signal includes atmospheric data which are not favorable to the entrapment of the harmful flying insects. The atmospheric data in question can be the external temperature, the external humidity rate, the atmospheric pressure, the wind speed, and others. This data can come directly from sensors placed outside the device A or come from local or regional weather stations;
    and / or allow the devices A to communicate with each other. To this end, referring to FIG. 11, when several devices A1, A2, A3 are networked and are adapted to communicate with each other, it may be advantageous for one of the devices A1 to be considered as a master and the others as slaves. The master device A1 collects the information and / or data coming from the slave devices A2, A3 and communicates them to a remote server Ser. A Lora® type communication solution is preferably used to facilitate internal dialogue between the A1, A2 A3 devices. The communication between the master device A1 and the remote server Ser is carried out using wireless communication means of the WIFI, 3G, or other type. This topology is particularly useful in geographic areas with low network coverage since it limits the master device A1 to the number of network points required on the installation;
    -24and / or remotely manage the operation of the appliance (s) A, for example using wireless communication means of the WIFI, 3G or other type;
    and / or send malfunction messages from device A to a remote server, for rapid management of any malfunctions.
    The arrangement of the various elements and / or means and / or stages of the invention, in the embodiments described above, should not be understood as requiring such an arrangement in all implementations. In any event, it will be understood that various modifications can be made to these elements and / or means and / or stages, without departing from the spirit and scope of the invention. In particular :
    - Boxes 10, 20, 40 are not necessarily rectangular, but can be polygonal, cylindrical, etc.
    - The suction port 220 can be circular, oval, rectangular, square, etc.
    - The chassis 4 is not necessarily rectangular or cylindrical in shape. It can be in any other form suitable for a person skilled in the art.
    - The suction means 23 can be in the form of a vacuum pump.
    - The means 6 for generating the flow Fb can be in the form of a mechanically actuated blown, or in the form of a pump.
    - The CO2 can be diffused according to a sinusoidal rhythm in the hollow chamber 15, for example according to the same rhythm as the operation of the fan 6.
    - The CO2 constituting the attractive gaseous cocktail can be replaced by any other gas suitable for a person skilled in the art.
    - Olfactory lures can be used in the form of gas.
    - An electrical resistance can be provided to heat the interior of the hollow chamber 5 and, if necessary, the refractory material that it contains.
    权利要求:
    Claims (12)
    [1" id="c-fr-0001]
    claims
    1. Apparatus for trapping harmful flying insects comprising:
    - a device (1) for diffusing, into the surrounding ambient air, an attractive gaseous cocktail, the composition of which is adapted to attract insects,
    - a suction device (2) having a suction opening (220) of a surrounding ambient air flow containing the insects attracted by the gaseous attractant cocktail diffused,
    - an insect trap (3) arranged with the suction device (2) so that the insects sucked by said device are retained in said trap,
    - a frame (4) containing a gas source (41) connected to the diffusion device (1), which gas is a constituent of the gaseous attractant cocktail, characterized by the fact that the diffusion device (1), the d suction (2) and the insect trap (3) form a structure (S) connected to the frame (4) via at least one means for adjusting the height of said structure, in the direction of separation or an approximation of the ground level of the suction orifice (220).
    [2" id="c-fr-0002]
    2. Apparatus according to claim 1, wherein the height adjustment means is in the form of at least one cross member (5) fixed to the structure (S), which cross member is secured to the frame (4) in a plurality vertical positions (50) for adjusting the spacing or approximation of the ground level of the suction port.
    [3" id="c-fr-0003]
    3. Apparatus according to claim 1, wherein the height adjustment means is in the form of at least one cross member (5) fixed to the frame (4), which cross member is joined to the structure (S) in a plurality vertical positions (50) for adjusting the spacing or approximation of the ground level of the suction port (220).
    [4" id="c-fr-0004]
    4. Apparatus according to one of claims 2 or 3, wherein a fluid connection is made between the gas source installed in the frame (4) and the diffusion device (1), which fluid connection passes through the au minus a crosspiece (5).
    [5" id="c-fr-0005]
    5. Apparatus according to one of the preceding claims wherein an electrical power source (42) is installed in the chassis (4), an electrical connection being made between said source and the structure (S), which electrical connection goes to the cross of the at least one cross (5).
    [6" id="c-fr-0006]
    6. Apparatus according to one of the preceding claims, wherein the frame (4) is in the form of a street lamp.
    [7" id="c-fr-0007]
    7. Apparatus according to one of the preceding claims, wherein an optical insect counter (30) is arranged at the suction port (220).
    [8" id="c-fr-0008]
    8. Apparatus according to one of the preceding claims, wherein the suction device (2) comprises a heating element (240) disposed at the suction port (220), upstream of said orifice.
    [9" id="c-fr-0009]
    9. Apparatus according to claim 8, wherein the heating element (240) is heated to a temperature between 35 ° C and 45 ° C.
    [10" id="c-fr-0010]
    10. Apparatus according to one of the preceding claims, in which the diffusion device (1) is controlled by a control unit (60) adapted so that the attractive gaseous cocktail is diffused into the surrounding ambient air according to a simulating sinusoidal rhythm. a human breathing rate.
    [11" id="c-fr-0011]
    11. Apparatus according to claim 10, wherein the control unit (60) is adapted to vary the frequency of the sinusoidal rhythm of diffusion of the gaseous attractant cocktail.
    [12" id="c-fr-0012]
    12. Method for trapping harmful flying insects, comprising:
    - diffuse, in the surrounding ambient air, an attractive gaseous cocktail whose composition is adapted to attract insects,
    - sucking, through a suction opening (220), a surrounding ambient air flow containing the insects attracted by the attracting gaseous attractive cocktail,
    - retain in a trap (3) the aspirated insects, characterized in that the method further comprises the steps of:
    - use a device (A) according to one of the preceding claims,
    - identify at least one species of harmful flying insects to be trapped,
    - adjust the height of the structure (S) of the device (A), in the direction of a spacing or approximation of the ground level of the suction orifice (220), which adjustment is carried out in depending on the identified species of harmful flying insects.
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    同族专利:
    公开号 | 公开日
    JP2021516068A|2021-07-01|
    BR112020018037A2|2021-02-09|
    US20200404897A1|2020-12-31|
    CA3093191A1|2019-09-12|
    SG11202008638XA|2020-10-29|
    FR3078608B1|2021-07-09|
    WO2019170996A1|2019-09-12|
    EP3761785A1|2021-01-13|
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    WO2016168347A1|2015-04-13|2016-10-20|University Of Florida Research Foundation, Inc.|Wireless smart mosquito and insect trap device, network and method of counting a population of the mosquitoes or insects|
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    US6779296B1|2003-02-07|2004-08-24|The Coleman Company, Inc.|Mosquito trapping apparatus utilizing cooled carbon dioxide|
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    法律状态:
    2019-03-29| PLFP| Fee payment|Year of fee payment: 2 |
    2019-09-13| PLSC| Search report ready|Effective date: 20190913 |
    2019-09-13| EXTE| Extension to a french territory|Extension state: PF |
    2020-03-27| PLFP| Fee payment|Year of fee payment: 3 |
    2021-03-22| PLFP| Fee payment|Year of fee payment: 4 |
    优先权:
    申请号 | 申请日 | 专利标题
    FR1851929|2018-03-06|
    FR1851929A|FR3078608B1|2018-03-06|2018-03-06|APPARATUS AND METHOD FOR TRAPPING PEST FLYING INSECTS|FR1851929A| FR3078608B1|2018-03-06|2018-03-06|APPARATUS AND METHOD FOR TRAPPING PEST FLYING INSECTS|
    PCT/FR2019/050485| WO2019170996A1|2018-03-06|2019-03-05|Apparatus for trapping harmful flying insects and method for counting trapped insects|
    SG11202008638XA| SG11202008638XA|2018-03-06|2019-03-05|Device for trapping damaging flying insects and method for counting insects trapped|
    BR112020018037-8A| BR112020018037A2|2018-03-06|2019-03-05|apparatus for capturing harmful flying insects in traps and method for counting captured insects.|
    CA3093191A| CA3093191A1|2018-03-06|2019-03-05|Apparatus for trapping harmful flying insects and method for counting trapped insects|
    JP2020570649A| JP2021516068A|2018-03-06|2019-03-05|Flying pest capture device and counting method of captured insects|
    US16/978,366| US20200404897A1|2018-03-06|2019-03-05|Device for trapping damaging flying insects and method for counting insects trapped|
    EP19717525.0A| EP3761785A1|2018-03-06|2019-03-05|Apparatus for trapping harmful flying insects and method for counting trapped insects|
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