The invention concerns a device for dropping in the atmosphere fragile products such as insects without damaging them and in controlled quantities. The invention also relates to a method for dropping, which implements the device and a transport means equipped with such a device.
The dropping of insects sterilised by irradiation or genetically modified in a natural environment has become a major way to fight certain diseases: malaria and arboviruses (Chikungunya, Dengue, Zika) with mosquitoes, African trypanosomiasis (sleeping sickness in humans and Nagana in animals) with the tsetse fly.
The dropped insects have been sterilised by irradiation or genetically modified so that their offspring is not viable. They come into competition with natural insects and contribute to their eradication. This enables to avoid the large-scale diffusion of pesticides. In other applications, parasitoids are dropped, for example Trichogrammae. These parasitoids feed off the larvae of harmful insects.
The drop must be performed in precisely-determined quantities as the device is intended for dropping products that are expected to have an effect on the environment, and the drop must enable to achieve a measurable effect in a predefined area.
Several devices for dropping fragile products in a natural environment and in precisely-measured quantities are known. One of the ways consists of using a worm drive. This system presents the disadvantage of damaging a large proportion of the fragile products. Devices using a vibration table are also known. The operation of these devices is disrupted by the vibration of the transport means (light aircraft) in which they are loaded on, and therefore lose the accuracy thereof. Finally, devices using a belt conveyor are also known, but they cannot be used to drop small quantities of insects and they injure the insects (see for example MXNL05000060).
For this purpose, the invention proposes a device for the dropping of fragile products comprising:
The device comprises mainly a means to store the fragile products to be dropped, such as a hopper, and a means to distribute the fragile products. The hopper conventionally comprises a discharge means, such as a narrowing and an orifice in the lower section during operations.
The distribution means comprises a support with cavities on the surface, i.e. open cavities that can be filled and then emptied. The support can be animated with a motion, such as rotation or back-and-forth, as will be described below, enabling, in the first position, to present a cavity facing the orifice of the discharge means of the hopper and, in the second position, to move this cavity away from the hopper. In the first position, the cavity is filled, by gravity, with fragile products, and in the second position it is emptied.
This arrangement, in itself, enables to control the dropping of fragile products, since the volume of the cavities and the frequency at which they present themselves in front of the orifice of the hopper can be adjusted by the user.
The difficulty consists of, on the one hand, avoiding the dispersion of the fragile products in the first position of the support, when the products pass from the hopper into the cavity, and on the other hand, avoiding damages to the fragile products when passing from the first to the second position of the support.
For this purpose:
According to the characteristics of the invention, which can be taken individually or in combination:
The invention also relates to a vehicle, such as an aircraft, comprising a device according to the invention.
The invention also relates to a method for dropping insects using a device according to the invention, comprising steps consisting of:
The method can further comprise a prior step consisting of cooling the storage means, so as to make or keep the insects lethargic.
It can also comprise a prior step consisting of loading the device into a vehicle such as an aircraft so as to drop the insects in flight.
Advantageously, the insects are sterilised by irradiation or genetically modified so that the offspring thereof is not viable.
Embodiments and different variants are described below, as non-limiting examples, with reference to the appended drawings, wherein:
The products 5 are stored in a hopper 4 following the vertical axis Z-Z′, in the operating position, having, such as represented, the shape of a funnel and comprising a discharge means 4a in the form of a partially-lower orifice, and a cover 4b in the upper portion. This hopper 4 is contained in an enclosure 8, advantageously an enclosure provided to maintain a setpoint temperature, as will be explained in further detail below. The orifice 4a opens onto the lower face 8a of the enclosure, which enables the products to flow from the hopper 4 and out of the enclosure 8.
A cylindrical support 2 is placed at a distance d under the lower face 8a of the enclosure. This cylinder is rotationally mounted about an axis A-A′ orthogonal to the axis Z-Z′ of the hopper. The support could have a shape other than cylindrical; it could for example be spherical. Depending on the intended use, the distance d is between 1 and 3 cm, although it is not limited thereto.
From the lower face 8a of the enclosure and at the periphery of the orifice 4a, in the direction of the cylinder 2, extends a set of flexible components (for example threads, filaments, hairs, thin strips, although not limited thereto) forming a brush 3. The components of the brush 3 form a soft wall defining a volume wherein the products 5 present in the hopper 4 can fall by gravity into a cavity of the support 2: this volume therefore brings the opening 4a of the hopper into communication with the cavity. The volume can be any kind of shape: cylindrical, conical, etc. This brush 3 is therefore different from other known brushes, in that it is substantially “hollow” and forms a flexible channel through which the products can flow from the orifice 4a of the hopper 4 towards a cavity 1a, 1b, without being dispersed.
Such as represented, the cylinder 2 comprises two cavities 1a, 1b at the surface thereof, the cavity 1b being concealed by the brush 3. The cavities 1a, 1b can be any shape, but preferably a spherical shape; for a greater volume, they can extend along a generator of the cylinder 2. The number of cavities at the surface of the support could be different than two.
The brush 3 has two purposes:
The length of the components of the brush 3 is such that the free ends of these components are in permanent contact with the surface of the support 2 and brush said surface as it rotates. The components of the brush 3 are not necessarily all of the same length. The free ends of these components form a curve that reproduces the shape of the intersection of the volume defined by the brush 3 and the support 2 in order to guarantee a good seal between the brush 3 and the support 2, and on the other hand, to limit the friction stress on the fragile products. Thus, in the event where the brush 3 defines a volume with a cylindrical shape with a circular base:
In addition, the arrangement of these components is such that, when the opening 4a is located facing a cavity 1a, 1b, the free ends thereof surround the periphery of the cavity, so as to prevent the dispersion of fragile products between the brush and the support 2.
When the support 2 continues the rotation thereof, the products 5 which had fallen in a cavity 1a, 1b are brushed by the brush 3 and can escape from the cavity. In
The device 10 thus enables to drop precisely-measured quantities of fragile products in the environment without damaging them. It is understood that it is easy to adjust the measured quantities by changing the shape and/or the number of cavities 1a, 1b, as well as the rotational speed of the support 2. In addition, this rotational speed is not necessarily constant, it being able to progress step-by-step.
The fragile products to be dropped are for example seeds, biocides, bacterial spores (such as sporulation as toxic protein crystal for the insects of, for example, Bacillus thuringiensis israelensis (Bti) and Bacillus sphaericus (Bs)), but the device is advantageously used to drop, in a precisely calibrated manner, insects that have been sterilised by irradiation or genetically modified to fight certain diseases such as malaria and arboviruses or African trypanosomiasis transmitted by glossina (tsetse fly). The dropped insects start competing with “natural” insects, but do not produce offspring. They can also be parasitoids.
In this case, it is useful that the insects are maintained at a relatively low temperature, of between 8° C. and 10° C., and therefore lethargic, inside the hopper 4. In this case, the enclosure 8 forms a thermal barrier and the device 10 comprises a means to supply cold or, alternately, is suitable for receiving cold bodies such as freezer packs that change phase at a given temperature and/or dry ice.
The insects do not all have the same fragility, and the components of the brush 3 are advantageously adapted to the type of insect to drop. For example, glossina is a relatively resistant fly and the hair or the threads of the brush 3 can be relatively rigid. In contrast, mosquitoes are fragile and the “hairs” of the brush 3 will have to be a lot softer in order not to injure them. The components of the brush 3 can be chosen from among natural fibres (boar bristles, etc.) or artificial fibres. They can also be flexible thin strips. A person skilled in the art will know how to select the type of fibre or thin strips suitable for any insect.
In the illustrated example, the plate 20 comprises two transversal cavities 10a, 10b. The plate 20 is moved in a back-and-forth motion so as to present facing the orifice 4a of the hopper 4, sometimes the first cavity 10a, and sometimes the second cavity 10b. When the cavity 10a is facing the orifice 4a (
For the cavity located facing the orifice 4a to fill without emptying at the same time, and to guide the products out of the cavity that is to be emptied, the plate slides between two fixed guides, an upper guide 11a and a lower guide 11b. The upper guide 11a comprises a transversal opening located facing the orifice 4a, so as to enable the filling of the cavity located facing the orifice 4a, and extends substantially on either side of this opening. On the contrary, the lower guide 11b comprises a full part located facing the orifice 4a.
In this manner:
To avoid injuring the fragile products during movements of the drawer of the support 20, the periphery of the openings 10a, 10b is advantageously equipped with small brushes 30.
In another version of this embodiment, the support 20 could be circular and rotationally-driven about an axis parallel to the Z-Z′ axis of the hopper.
Number | Date | Country | Kind |
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1653994 | May 2016 | FR | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2017/059832 | 4/25/2017 | WO |
Publishing Document | Publishing Date | Country | Kind |
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WO2017/190991 | 11/9/2017 | WO | A |
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20190141946 A1 | May 2019 | US |