SPRAY UNIT, COMPACT SPRAY MODULE COMPRISING SUCH A UNIT AND SPRAY AND PILOTAGE SYSTEM COMPRISING A P

专利摘要:
The present invention relates to a spraying unit, for spraying a liquid on vegetation, comprising a nozzle formed by a tube (1), a rotary atomizer (3) and a fan generating a carrier air flow around the latter, a drive system, routing means for conveying the liquid up to said atomizer able to break it into droplets. The nozzle (1) encloses a fuselage (5) surrounded by the flow of carrier air and comprising a rotary section formed by the rotary atomizer (3) whose rotation drives the propulsion, preferably substantially perpendicular to the longitudinal axis (X ), droplets in the flow of carrier air. It also relates to a compact spray module comprising such a unit and a spray and control system comprising a plurality of such modules.
公开号:FR3037826A1
申请号:FR1555894
申请日:2015-06-25
公开日:2016-12-30
发明作者:Roger Pellenc；Jean-Marc Gialis
申请人:Pellenc SAS；
IPC主号:

专利说明:

[0001] DESCRIPTION The invention is in the field of apparatus projecting a liquid in the form of droplets mixed with a flow of carrier air on a target consisting for example of a plant mattress, and has for object a spraying unit. It also relates to a compact spray module comprising such a spray unit and a spray and control system comprising a plurality of such modules. It is applicable in particular in the agricultural field for the treatment of arable crops, arboriculture or viticulture. It will be described below for the sake of simplification in its application to the wine sector, requiring significant inputs of phytosanitary products. The contribution of these in nature can generate more or less long term serious consequences in terms of health as well as ecologically but also economically. These products are indeed one of the main sources of pollution of water, soil and groundwater and their inhalation or even their ingestion has irreversible consequences on the health of users. In economic terms, besides the high cost of the products and their implementation, the inefficiency of a treatment can cause irreversible damage to the crop.
[0002] In this context, the public authorities in recent years have tightened the standards on treatment equipment, requiring, for example, in France a mandatory technical inspection every 5 years of spray equipment. In another axis, active ingredients identified as being the most dangerous are prohibited or their approved dose reduced.
[0003] It is clear that these standards will continue to evolve in the future and thus further tighten the regulatory status of machinery and products. This development requires the design of new spraying machines that make it possible to judiciously use minimal doses of active ingredient to a targeted plant target while limiting their energy consumption to preserve both the environment and the health of the plants concerned, as well as that of the operators having to control such machines. Several types of sprayers used in the vineyard are known for cover treatments or located in the zone 3037826 - 2 - bunches of grapes, including the following four types of sprayers: jet, air blast, pneumatic and centrifugal . All these devices have in common the projection on the vegetation of porridge (term used to define the liquid to be sprayed usually composed of a mixture of water and active material) which is conveyed in liquid form and under pressure in a pipe leading to to a spray nozzle. The slurry is micronized into droplets at the nozzle, and directed to the vegetation by various means depending on the technology of the spray apparatus. The nozzle 10 comprises a calibrated nozzle, most often constituted by the orifice formed in a thin wafer, this orifice passing through the wafer may have various shapes (cylinder, prism, cone, etc.) but of small size. to be able to transform the liquid under pressure upstream into droplets downstream. The nozzle defines the spray rate that will be sprayed and the size of the droplets. This slurry flow rate is however not precisely controlled because it depends in particular on the pressure conditions of the upstream liquid, which are different for each nozzle, as a function of the geometry and length of pipe between the pump and the nozzle, and of the wear. during the time of the nozzle due to the abrasion of its orifice at the passage of the products.
[0004] In jet projectors, generally comprising a plurality of nozzles to cover the area to be sprayed, the slurry is formed into droplets at each nozzle by the combined effect of the liquid pressure upstream of the nozzle. and the geometry of the nozzle, which effect also communicates to said droplets a kinetic energy and a direction of their spraying. The droplets are thus projected directly into the ambient air generally in the form of a larger or smaller angle spreading cone also depending on the shape of the nozzle and the pressure of the slurry upstream thereof. latest. On the other hand, the higher the pressure of the slurry, the more the droplets formed at the outlet of the nozzle will have a high speed but they will then be small, limiting their kinetic energy and therefore their ability to reach the leaves and clusters, adding the fact of their evaporation between the exit of the nozzle and the targeted vegetation. Droplets may also be subject to significant drift in the event of wind. It is also known on this type of device that a large variation in pressure generates only a small variation in flow, while greatly varying the size of the droplets. This type of apparatus then defines an optimum operating between the pressure and the nozzle at each nozzle which allows little or no adjustment of the spray rate to spray the target vegetation, it is that is, the flow is not controlled upstream of the nozzle. Changing the spray rate to the vegetation then requires changing all nozzles (or their nozzles) by a long, tedious human intervention and requiring the wearing of safety equipment. In airblast devices, the slurry is still delivered under pressure at the nozzle with an effect similar to the jetjets being sprayed. In this technology, however, a high-speed air flow (large airflow at speeds of 100 to 200 km / h) will surround the nozzle to carry the droplets to the vegetation, increasing the speed of droplets towards the targeted vegetation and favoring their penetration. This air flow is provided by a centralized ventilation system on the machine 15 and will then be channeled to each spray nozzle. Thus, with a blast device, the size of the droplets is always determined by the combination of the pressure and the nozzle, but it is essentially the airflow at the nozzle that will carry the droplets in a trajectory oriented towards the targeted vegetation, greatly reducing the sensitivity of said trajectory to the influence of the external winds, and by limiting the evaporation of the droplets during their trajectory. However, like spray jet technology, the flow rate at each nozzle is only indicative, uncontrolled, different from one nozzle to another and can vary only over a small flow range, requiring changing the nozzles (or their nozzle) to change the spray rate of the slurry. In addition, the air required for the constitution of the air flow is generated centrally and then distributed to the different nozzles through a long and complex pipe circuit generating significant pressure losses, different air velocities and not controlled from one nozzle to another as well as superabundant energy consumption. The high power turbines used here are also particularly noisy. In contrast to jet or jet devices, pneumatic devices directly form the droplets from an accelerated high velocity airflow at the nozzle (typically 35,300 to 500 km / hr) spark gap (often a simple nozzle). The slurry is pressurized at the spark gap to form a vein of non-micronized liquid in the absence of airflow. The high-speed air flow is accelerated at the spark gap (for example by venturi effect) to generate the micronization of the liquid vein into droplets. The size of the droplets on such devices is related to the speed of the airflow closely related to the flow of the slurry at the level of the spark gap.
[0005] 5 A change of air speed must then always be accompanied by a change of flow, and generally nozzles of the spark gap, so as not to penalize the spray quality. And conversely, a change of nozzle to change the flow will also need to adapt the speed of the airflow. The operating principle of these devices also generates, like the previously mentioned technologies, flow rates and air velocities different from one nozzle to another resulting in the spraying at the level of the targeted vegetation of a flow rate. indicative and uncontrolled porridge. The generation of airflow is also centralized, highly energy-consuming and particularly noisy.
[0006] The major drawbacks of these first 3 technologies can be summarized as follows: the spraying parameters, such as for example the flow rate or the air velocity, are indicative at each nozzle, different from one nozzle to another and drift over time, in particular following the wear of the nozzles. These systems therefore do not make it possible to precisely control and control these spray parameters at each nozzle, just as they do not make it possible to vary these parameters over a large range with the same nozzle to be adapted instantaneously to the nozzle. vegetation encountered during treatment. However, many factors such as the nature of the field, the age and the grape variety of the vine, can result in very different amounts of plant mass from one vine to another which would necessitate porridge flows that can be modified. quickly and on important beaches to adapt to the masses of vegetation opposite the spray nozzles. This point encourages the operator to position the calibrations (nozzles, nozzles, spark gaps) of state-of-the-art machines at their maximum speed so as to avoid wasting time changing them as much as necessary. which then leads to an overabundant consumption of porridge. It is therefore not conceivable with these technologies to imagine dynamic variations of the spraying parameters on the vegetation encountered during treatment, the change of flow rate, the adjustment, the cleaning and the maintenance require a long human intervention and tedious that, considering the toxicity of the slurries, requires the use of individual protections and operating protocols very restrictive, or even unrealizable (change dozens of nozzles or nozzles to change a flow or change the product of treatment, cleaning tanks and slurry pipes, etc.), - the small size of the nozzles to ensure the effectiveness of micronisation imposes a slurry with a high dilution rate of plant protection products to prevent their clogging by agglomerates poorly dispersed slurry in the water, thus preventing from working with low spraying volumes of sprays (Less than 100 liters per hectare, for example, whereas conventional volumes vary in the range of 200 to 800 liters per hectare depending on the vegetation and the type of spray mixture). In fact, the autonomy of the sprayer, given the high dilution rate of plant protection products, requires spraying assemblies comprising large tanks of 1000 to 2000 liters of liquids, and therefore equivalent volumes of clear water. The weight of this assembly requires powerful tractor vehicles to combine the traction of the spray assembly and its operation, the necessary pressures at the level of the nozzles are high, which can easily reach values of the order of 30 bar, causing expensive, heavy and cumbersome technology pumps, and requiring significant energy dissipated at the pump. the generation of the air flow in pneumatic or air-blast technologies is done by means of a large, very noisy, large-diameter turbine generally associated with a network of flexible ducts which cause significant losses of loads, requiring oversizing of the turbine and makes a power of the order of 30 kW causing greater consumption of the towing vehicle. In addition, the turbine has a high inertia which generates a starting time and stopping thereof for a period of several seconds that does not allow frequent stop and start sequences during treatment (end of rank, peak, momentary absence of vegetation, maneuver ...), which then leads to unnecessary and polluting consumption of porridge and fuel.
[0007] Centrifugal technology, which is the latest in this field, solves some of the problems posed by the other three aforementioned technologies. The object of the document FR 2 497 439 is a spraying installation using centrifugal technology, in which the droplets are formed by a large diameter rotary nozzle, on the central part of which a nozzle projects the spray mixture. A collector in the form of a ring sector, of fixed or adjustable angle, is fixed opposite the periphery of the rotary nozzle, without contact with it, so as to intercept the pulverized spray in the sector corresponding to the collector and to limit the spray zone at the portion corresponding to the free sector of the collector. The droplets are here formed by bursting due to the centrifugal force of the liquid slurry stream when it reaches the end of the rotating nozzle. This rotary nozzle technology has the advantage of spreading small quantities of slurry, which would require in other technologies to significantly reduce the size of the nozzles to obtain a low slurry flow, thus increasing the risk of clogging of those -this. While using the same nozzle and thus a given flow rate of slurry arriving on the nozzle, the appropriate choice of the angle covered by the collector shaped ring sector can adjust a flow of pulverized spray to the vegetation depending on the size of the open sector in the collector and therefore inevitably less than the flow of spray arriving on the nozzle. However, the installation of document FR 2 497 439 has the following drawbacks: the portion of slurry not spilled on the vegetation is normally recycled by the collecting ring. But some of this slurry is lost uncontrollably by overflow or draining of the recycled product from the collector, resulting in loss of slurry and unwanted pollution of the environment. Thus, all the slurry arriving at the nozzle is not directly and totally projected towards the vegetation, the recycled slurry loses its characteristics because of its exposure to the atmosphere: the concentration of active products is modified because of a first spraying (by evaporation of water for example), the slurry can be recycled several times before being spread on the vegetation. Thus, the quality of the slurry sprayed to the vegetation is not constant, the slurry flow projected towards the vegetation depends on the opening angle of the free sector of the collector. It is therefore impossible to modify this flow rate on the same portion of plant mattress with respect to the free sector, since only then a larger portion of plant mattress will be impacted by the opening of the free sector of the collector. The change of flow rate on an identical portion of plant mattress 5 will then require the change of the nozzle with the disadvantages of the previously mentioned technologies, - the projected flow towards the vegetation is indicative and can not be controlled precisely given the losses and recycling of liquid mentioned above, - the kinetic energy of the droplets to reach the vegetation is generated solely by the rotating nozzle. We thus find the disadvantages of the projected jet technology. Still in the centrifugal technology using rotating nozzles having the effect of micronizing a liquid, that is to say a slurry in liquid form in droplets, US6152382 relates to a modular spraying apparatus including at least one module of spray comprising a nozzle formed by a cylindrical tube open at both ends, said nozzle generating a flow of carrier air generated by an axial fan positioned at one of its ends, said carrier air stream acting at the outlet of the nozzle on a rotary nozzle, also known as a rotary atomizer, in the form of a conical piece whose end protrudes from the exit opening of the nozzle to the outside of the latter. Said carrier air flow is, however, decomposed into two laminar air streams, namely an axial laminar air flow around the rotary nozzle and oriented axially so as to distribute the slurry uniformly over a small thickness of the conical portion of the air. the rotary nozzle and imparting kinetic energy to the centrifugally generated droplets at the end of the rotary nozzle in a predictable direction, and a helical laminar airflow organized around the axial laminar airflow, mixing the two effected between the exit of the module and the plant mattress, to make the droplets penetrate all the faces of the leaves of said plant mattress. The slurry is conveyed in each module by a feed tube passing through the wall of the enclosure of the corresponding module to open at the conical outer surface of the rotary nozzle in an area covered by the axial laminar air flow, from a central tank and via one or more pumps (one pump per spray bar of several modules) remote from the module providing an indicative flow rate at each module and the conditions of similar throughput from one module to another. The flow rates at each module are therefore not controlled and can not be modulated in substantially different ranges from one module to another. In addition, with the type of apparatus disclosed in US6152382, the slurry arrives on the conical surface of the rotating nozzle surrounded by the axial laminar air flow generating a dripping by combination of the effect of gravity and the suction generated by the flow of axial laminar air at the inlet tube followed by a detachment of large drops in the axial laminar air flow, or through the two successive airflow laminar flows to end out of the surface targeted plant. Moreover, the vortex effect of the helical laminar airflow considerably lengthens the path of the droplets between the outlet of the module 15 and the plant, increasing the risk of drying the droplets during this journey, the latter in fact rapidly losing the energy needed to reach the target plant. But also, the means developed for generating each airflow laminarly in the form of two sets of multilayer channels considerably increase the friction surface between the air and these channels and therefore the pressure drops inside the modulus, these being further accentuated in the air shear zone generated at the interface of the two laminar air flows, outside the module during mixing between the two laminar air flows, but also during their interaction with the ambient air at the output of the module. The electrical efficiency of the system is thus seriously affected. Moreover, this system requires the establishment of two engines per module to generate both the two laminar air streams and secondly the micronization of the slurry, which has the result of increasing the weight, congestion and complexity of system management. Finally, the introduction of solenoid valves at a distance from the module making it possible to dispense the slurry arriving on the rotary nozzle does not make it possible, in the event of a power failure of the slurry, to instantaneously stop the production of drops or droplets. taking into account the direct interaction of the axial laminar air flow on the arrival of slurry from the rotary nozzle and the unavoidable suction by the axial laminar air flow 35 of the quantity of slurry between the solenoid valve and the end of the feed tube. The aim of the present invention is to overcome at least one of these disadvantages by proposing a spray unit designed to receive a controlled variable flow liquid and the suction of ambient air to generate a flow of air capable of carrying air. projecting at the outlet or downstream of the spraying unit said mixed air stream of said liquid in the form of droplets to a target, with high dynamics, excellent energy efficiency and very low environmental impact. Controlled variable flow liquid means the flow of a liquid coming from a reservoir and supplied by a liquid supply system under the control and / or control of an electronic intelligence, for example a control unit. control and electronic control operating on the basis of a microprocessor, for regulating a given flow rate according to a corresponding flow setpoint and regardless of the pressure in the hydraulic circuit.
[0008] Very low environmental impact is defined as the fact that it is possible to avoid the projection of slurry outside the targeted vegetation, to be able to spray the right quantity of slurry by adapting during spraying the slurry flow in a controlled manner according to the targeted vegetation, to avoid any loss of slurry by dripping to the ground, to be able to stop spraying instantaneously in the absence of vegetation, to be able to limit the consumption of clear water for the slurry or the cleaning of the system and finally to drastically limit the energy required for the spraying operation. For this purpose, the spraying unit, according to the present invention, for spraying a liquid in the form of droplets for the treatment of a target, such as for example a vegetable hedge, said spraying unit comprising a nozzle formed by a duct extending along a longitudinal axis delimiting internally a main internal space and being open at its ends to form an air inlet opening and an air outlet opening, the space main internal receiving at least one rotating atomizer rotatably mounted about a first axis of rotation, conveying means for conveying the liquid from a supply system with a controlled variable flow to the atomizer rotary, a fan having at least one propeller rotated about a second axis of rotation and for generating a flow of carrier air in the main internal space to and beyond the opening an air outlet and an electric motor drive system (s) for providing rotational driving of said rotary and propeller atomizer, said rotary atomizer comprising a receiving surface provided for receiving the liquid and ensuring, at its periphery or its end, the rotational state of said rotary atomizer, the fragmentation of the liquid into droplets and their propulsion in the flow of carrier air, and connection means to a source power supply for supplying electrical energy to the drive system, characterized in that it further comprises an inner fuselage having an airfoil defined by a side surface 10 internally defining a secondary internal space and being axially held in the main internal space between the fan and the air outlet opening so as to define, between the fuselage and the nozzle, a channel annular circulation of the flow of carrier air surrounding said fuselage, in that the fuselage comprises a rotary section formed by the rotary atomizer so that the periphery or the end of the receiving surface is substantially in the surface lateral fuselage while allowing rotation of the rotary atomizer and propulsion, preferably substantially perpendicular to the longitudinal axis, said liquid in the form of droplets in said channel to be incorporated in the air flow.
[0009] The present invention also relates to a compact spray module for spraying a liquid in the form of droplets for the treatment of a target, such as for example a vegetable hedge, essentially characterized in that it comprises: a spraying unit as defined according to the invention; a liquid supply system operably connected to the conveying means of said spraying unit, said supply system comprising an electric pump, preferably a positive displacement pump; , more preferably a peristaltic pump, optionally associated with a flow sensor, for discharging, with a controlled variable flow rate, the liquid from a reservoir into said conveying means and a connection interface enabling said auditing system for receiving the liquid from the reservoir, - a support for fixedly holding the electric pump in the vicinity of the spraying unit, an electronic control and / or control unit, for example implanted on an electronic card, designed to control and / or control the operation of the drive system and the system 3037826 - 11 supply of liquid being functionally connected to said drive and liquid supply systems; an electrical connection interface allowing the connection of the drive system, the electronic control and / or control unit; and a liquid supply system to a source of electrical energy to provide their power supply. Such a spray module may also be provided to be connected in a spray and control system comprising a plurality of spray modules and a central control unit.
[0010] To this end, the module may further comprise a communication interface for connecting the electronic control unit and / or control unit to the central unit, in order to allow individual remote control of said module, independently of the others. modules, to instantly adapt at least one spraying parameter. Finally, the present invention also relates to a spraying and control system intended to be loaded onto a machine or a mobile machine, said system comprising a plurality of spray modules for spraying a liquid in the form of droplets for the treatment of a target such as for example a vegetable hedge, said liquid coming from a tank, essentially characterized in that it further comprises a control panel comprising an electronic central control unit, a man-machine interface, said HMI, connected to the latter, each spray module consisting of a compact spray module as defined according to the present invention and in that the electronic control central unit is functionally connected to each spray module so as to allow individual remote control of each spray module, independently of the other (s) spray modules, from said control panel to individually adjust the spraying and operating parameters of each spray module. In such a spraying and driving system according to the invention, the control panel may also comprise at least one input interface capable of receiving sensor signals from a detection system such as a signal representative of the presence or absence of a target, or parameters characterizing said target, or the parameters provided by the towing vehicle such as its speed or acceleration. The invention will be better understood, thanks to the following description, which refers to a preferred embodiment, given by way of non-limiting example, and explained with reference to the appended diagrammatic drawings, in which: FIG. 1 shows a perspective and exploded view of a module according to the invention comprising a spraying unit according to the invention, in the mounted state of the latter, with a atomizer of the rotary atomizer type in a first embodiment. FIG. 2 shows a longitudinal sectional view of the module shown in FIG. 1 in the assembled state; FIG. 3 shows a partial perspective and partial exploded view of the spray unit shown in FIG. FIG. 4a shows a partial perspective view of the spray unit shown in FIG. 3 in the assembled state, with the nozzle and the fuselage shown in FIG. so as to reveal the main internal space of the nozzle and the secondary internal space of the fuselage, FIG. 4b shows the spray unit shown in FIG. 4a, with the fuselage 5 in its entirety, FIG. 5 shows a perspective view of the spray unit shown in FIG. 4, at its distal end including the air outlet opening, and in a second embodiment of the rotary atomizer, FIG. 6 shows a perspective view, with partial tearing of the feed and distribution piece and a perspective view of the rotary atomizer, traversed axially by the common drive shaft and shown in FIG. 3; FIG. 7 only shows the feed and distribution part, shown in FIG. 6, on the end side having the feed orifices; FIG. 8 shows a perspective view of a ramp of several modules; of a module-type spray and control system shown in FIG. 1, FIG. 9 shows a perspective view of the module shown in FIG. 1, in the assembled and projected state of the liquid in the form of a droplet brush; FIG. 10 shows a rear view of a mobile machine carrying a plurality of modules, carried by ramps, of a spray and control system according to the invention, Fig. 11 shows a block diagram of the spray and control system according to the invention; Fig. 12 shows a partial cross-sectional view along AA of the spray unit shown in Fig. 2. It can be seen from Fig. the appended figures a spray unit for spraying a liquid 18 in the form of droplets 18a for the treatment of a target 21, such as for example a vegetable hedge, said spray unit comprising a nozzle 1 formed by a duct 15 extending along a longitudinal axis X delimiting internally a main internal space 1c and being open at its ends to form an air inlet opening 1a and an air outlet opening 1b. The main internal space 1c receives at least one rotary atomizer 3 rotatably mounted about a first axis of rotation X1, conveying means 8, 9 for conveying the liquid, coming from a supply system with a variable controlled flow, up to the rotary atomizer 3, a fan 2 comprising at least one propeller 2a rotatably mounted about a second axis of rotation X2 and for generating a flow of carrier air in the main internal space 1c to and beyond the air outlet opening lb 25 and a drive system 4, 4a motor (s) electrical (s) for ensuring the rotational drive of said rotary atomizer and propeller. The rotary atomizer 3 comprises a receiving surface 3a provided for receiving the controlled variable flow liquid and for ensuring, at its periphery or end 3b, the rotational state of said rotary atomizer, the fragmentation of all of said liquid. received in droplets propelled by centrifugal effect in the flow of carrier air, and connection means 6 to a source of electrical energy 22 for supplying electrical energy to the drive system 4, 4a. The liquid 18 is also commonly referred to as a slurry in the wine-making trade. The electric power source 22 may consist, for example, of an electric generator coupled to a moving machine 23 such as a towing vehicle. the energy being distributed by a power supply network 30 (Figure 11). According to the present invention, such a spraying unit further comprises an inner fuselage having an airfoil defined by a lateral surface 5a internally delimiting a secondary internal space 5b and being maintained substantially coaxially in the main internal space between the fan 2 and the air outlet lb so as to define, between the fuselage 5 and the nozzle 1, an annular channel for circulating the flow of carrier air surrounding said fuselage.
[0011] Still in accordance with the present invention, the fuselage 5 comprises a rotating section formed by the rotary atomizer 3 so that the periphery or end 3b of the receiving surface 3a substantially fits into the lateral surface of the fuselage 5 by allowing rotation of the rotary atomizer 3 and centrifugal propulsion, preferably in a direction substantially perpendicular to the longitudinal axis X, of the droplets in said channel to be incorporated in the air stream. The fuselage 5 comprises a rotary section formed by the rotary atomizer 3 so that the periphery or the end 3b, preferably smooth, of the receiving surface 3a substantially fits in the lateral surface of the fuselage 5 while allowing the rotation of the rotary atomizer 3 and the propulsion, preferably substantially perpendicular to the longitudinal axis X, of the droplets in said channel. Such an annular channel for circulating the flow of air can then concentrically surround the fuselage 5 along the longitudinal axis X of the nozzle 1. The conveying means 8, 9 receiving the liquid to feed the rotary atomizer 3 in the spraying unit may be provided for connection to a liquid supply system 7, 11, 8, 9 which may comprise an electric pump 11 and a hydraulic connection interface 7 allowing the latter to receive the liquid contained in a reservoir 26 (Figures 1, 2, 9, 11). In the operating state of the spraying unit, the rotary atomizer 3, more particularly the periphery or the end 3b of the rotatable receiving surface 3a can thus be entirely surrounded by the flow of carrier air generated by the fan 2 so as to be able to project all the droplets into the annular channel for circulating the flow of air 3 03 7 8 2 6 16 The drive system 4, 4a may comprise at least one electric motor 4, preferably an engine without brushes, and at least one drive shaft 4a for rotating the rotary atomizer 3 around the first axis of rotation X1 and the helix 2a around the second axis of rotation X2 (FIGS. , 4a, 4b). Preferably, as can be seen in Figures 2, 3, 4a, the drive system may comprise a single common electric motor 4 and a single drive shaft 4a common rotated about its axis X1, X2 by said electric motor. In addition, the common electric motor 4 and drive shaft 4a can make it possible to ensure both the rotation of the helix 2a about the second axis of rotation XI and the rotation of the rotary atomizer 3 around the first axis of rotation X2. The first and second axes of rotation X 1, X 2 can then be merged so as to enhance or improve the compactness of the spray unit along this axis and from the spray module according to the invention described hereinafter. The applicant has carried out numerous tests showing that the rotational speed variation range of the helix 2a generating the carrier air flow, combined with the droplet size obtained by the rotary atomizer 3 in this range had characteristics tuning satisfactory and incommensurate with existing technologies. Thus, the embodiment based on a common electric motor drive system has the effect of simplifying the realization and management of the module while increasing its compactness and reliability. It has also been demonstrated that the rotary atomizer has the ability to convert into droplets a liquid flow rate that can vary over a very wide range, which is also out of proportion with existing solutions, and all of the droplets are mixed in. case quite homogeneously in the airflow without noticing loss of liquid by dripping. In addition, the applicant has noted in the viticulture trials very significant energy consumption gains compared to the main technologies used to date. More particularly, if desired, the brushless motor has the advantages of a fast rotational speed, preferably more than 15,000 rpm, low inertia for fast rotational speed changes, and a low mass. The fuselage 5 may comprise at least one cooling section surrounding the electric motor (s) 4 and being in contact with each other. The drive system 4, 4a may comprise at least one electric motor 4, preferably a bruschless motor, and at least one drive shaft 4a for rotating the rotary atomizer 3 about the first axis of rotation X1 and the helix 2a around the second axis of rotation X2 (FIGS. 2, 3, 4a, 4b ). Preferably, as can be seen in Figures 2, 3, 4a, the drive system may comprise a single common electric motor 4 and a single drive shaft 4a common rotated about its axis X1, X2 by said electric motor. Further, the common electric motor 4 and drive shaft 4a can provide both rotation of the helix 2a about the second axis of rotation X1 and rotation of the rotary atomizer 3 around the first axis of rotation X2. The first and second axes of rotation X1, X2 can then be merged so as to enhance or improve the compactness of the spray unit along this axis and thus from the spray module according to the invention described hereinafter. The applicant has carried out numerous tests showing that the rotational speed variation range of the helix 2a generating the carrier air flow, combined with the droplet size obtained by the rotary atomizer 3 in this range had characteristics tuning satisfactory and incommensurate with existing technologies. Thus, the embodiment based on a common electric motor drive system has the effect of simplifying the realization and management of the module while increasing its compactness and reliability. It has also been demonstrated that the rotary atomizer has the ability to convert into droplets a liquid flow rate that can vary over a very wide range, which is also out of proportion with existing solutions, and all of the droplets are mixed in. case quite homogeneously in the airflow without noticing loss of liquid by dripping. In addition, the applicant has noted in the viticulture trials very significant energy consumption gains compared to the main technologies used to date. More particularly, where appropriate, the bruschless motor has the advantages of a fast rotational speed, preferably more than 15,000 rpm, a low inertia for fast rotational speed changes and a high speed of rotation. low mass. The fuselage 5 may comprise at least one cooling section surrounding the electric motor (s) 4 and being in contact with the flow of carrier air to evacuate from said contact a portion of the heat generated by the electric motor (s). . The or each section may be made of aluminum or other material promoting cooling or limiting the heating of the electric motor or motors arranged in this fuselage section 5. The receiving surface 3a of the rotary atomizer 3 may extend in a plane substantially perpendicular to the longitudinal axis X of the nozzle 1, so as to be able to eject the droplets in a direction substantially perpendicular to the longitudinal axis X of the nozzle 1 10 and at different distances between the fuselage and nozzle according to their shape and mass where they will then be deflected by the flow of carrier air to be incorporated substantially homogeneously to the latter, as shown theoretically in Figures 4a and 5 which do not take into account in this case of their taking into account and their deviation by the flow of carrier air. In a preferred embodiment, the rotary atomizer 3 may generally have a disc or frustoconical or conical piece shape and at least one of the outer faces of the disk or of the frustoconical or conical piece may form the receiving surface 3a. (Figures 2, 3, 4a, 5, 6). The fuselage section 5 and / or the nozzle 1 may be variable in size and / or shape along its longitudinal axis, as can be seen in Figures 2, 3, 4a, 4b and 5. By For example, the section of the nozzle 1 may be provided to be enlarged at its inlet and outlet openings 1a, 1b. Preferably, the air outlet opening 1b may have an oval shape. Thus, the droplet brush obtained at the outlet of the nozzle, may have an oval shape and substantially flattened at the level of the vegetation. Such an oval shape is particularly effective for obtaining a homogeneous brush, in combination, if appropriate, with the diffuser device 15. The rotary atomizer 3 can be pierced centrally and axially by a bore 3c to allow the passage of the shaft 4a driving its rotation around the first axis of rotation X1 (Figures 2, 3, 4a, 6) via a drive connection such as for example a connection by pins, keys, splines or teeth, or, as one can be seen in Figures 1, 3, 4a, 4b, 6 by pinching or jamming on the drive shaft 4a or force fitting of the latter in the bore 3c. The drive shaft 4a can also be provided in a variant, being made in one piece with the rotary atomizer 3 (Figure 5). In a preferred embodiment of the conveying means 8, 9, it can be seen, in particular in FIGS. 3, 4a, 4b and 5, that these can comprise a main supply duct 8 designed to receive the liquid from the liquid supply system 7, 11 and for supplying liquid, directly or indirectly, at at least one feed point, the rotating receiving surface 3a. In addition, the fuselage 5 may include a lateral liquid supply extension 5d 5 which may have an aerodynamic profile and in which can pass at least a portion of the main supply conduit 8 integrated or reported in said extension. The lateral liquid supply extension 5d may be provided to be able to extend transversely, preferably substantially perpendicularly, to the longitudinal axis X of the nozzle 1 in the annular circulation channel of the carrier air flow. Referring to FIGS. 2, 3, 4a, 6 and 7, it can be seen that in the case where such a main supply duct 8 is provided for indirectly supplying liquid to the receiving surface 3a, the invention that the conveying means 8, 9 may furthermore comprise for this purpose at least two secondary supply ducts 9 each intended to be connected to said main supply duct 8 and to be located in the secondary internal space 5b of the fuselage 5 The spraying unit may furthermore comprise an intermediate feed and distribution piece 12 which may comprise the secondary feed ducts 9 and which can be arranged in the secondary internal space 5b of the fuselage 5 between, on the one hand, , the fan 2, if necessary the electric motor 4, and, secondly, the rotary atomizer 3, in the immediate vicinity of the latter so that each secondary supply duct 9 can lead to 30. the difference of the carrier air flow opposite and in the immediate vicinity of the receiving surface 3a to supply liquid at least two feed points, preferably distributed on either side of the first axis of rotation X1, where appropriate on either side of the drive shaft 4a for ensuring the rotation of the receiving surface 3a around the first axis of rotation Xl. The high-speed rotation of the rotary atomizer 3, and from its receiving surface 3a, has the effect of distributing, outside the flow of carrier air, the liquid received by the latter until the periphery or end 3b of said receiving surface 3a, that is to say until one or one of the edges forming its periphery or its end, where the liquid will be broken up into droplets which will then be projected immediately by effect 5 centrifugal in the carrier air flow surrounding the rotary atomizer 3 and in particular the periphery or the end of its rotary reception surface 3a. Referring again to FIGS. 2, 3, 4a, 6 and 7, it can be seen that the intermediate feed and distribution piece 12 may comprise an annular liquid distribution groove 12a which may comprise at least two orifices. 12b each opening into one of the secondary supply ducts 9. In addition, the main supply duct 8 can be provided to open into the annular groove 12a which can thus ensure the distribution of the liquid, conveyed from the electric pump 15 11 by the main supply duct 8, in the secondary supply ducts 9. Preferably, as can be seen in particular in Figures 6 and 7, the intermediate feed and distribution piece 12 may have a generally cylindrical and can be pierced at one of its end faces, which can be oriented for example by being turned towards the outlet opening or air inlet 1a or 1b of the nozzle 1, by at least two feed holes 12d respectively forming the liquid supply points. In addition, the annular distribution groove 12a can be made in the external lateral face of the feed and distribution part 12 and the secondary feed ducts 9 can be made in the material of the intermediate feed piece and distribution 12 so as to open at one of their ends in the annular groove 12a and at their other end in one of said feed holes. On the other hand, the fuselage 5 may be designed in its part 30 receiving the intermediate feed and distribution piece 12 to surround the annular groove by providing a fluid seal with the latter. The feed and distribution intermediate piece 12 may be traversed axially by a through bore 12c allowing the driving shaft 4a to pass, rotating the rotary atomizer 3 (FIGS. 2, 3, 4a, 6 and 4). 7) by means of a drive connection, not shown. The fuselage 5 extends longitudinally or axially between two ends, one of which, said distal end, is, in the state mounted in the nozzle 1, the farthest from the fan 2 or the nearest of the output aperture lb and the other, said proximal end, is farthest from the exit aperture lb. In a preferred embodiment of the axial or longitudinal position of the rotary section of the fuselage 5 formed by the rotary atomizer 3, the invention can provide that the rotary section can form the distal end of the fuselage 5 (FIGS. 3, 4a, 4b, 5, 9). As can be seen in FIGS. 1, 2, 3, 4a, 4b and 5, the lateral surface 5a of the fuselage 5 may be closed or perforated, continuous or discontinuous. Preferably, in order to provide an increased efficiency of the flow of air flow along the fuselage at least to its rotary portion formed by the rotary atomizer 3, the lateral surface 5a can be closed; that is, continuous along the fuselage 5 at least between, on the one hand, its proximal end and, on the other hand, the rotary atomizer 3 or an area located near the latter. In a first embodiment of the fuselage 5, as can be seen in Figures 1, 2, 3, 4a, 4b, 9, the receiving surface 3a of the rotary atomizer 3 can be located in the secondary internal space 5b and 20 the axial or longitudinal continuity of the lateral surface 5a of the fuselage 5 can be interrupted by a transverse passage slot 5c allowing the droplets to be propelled into the flow of carrier air through the lateral surface 5a of the fuselage 5. The slot 5c may be delimited by two external peripheral edges vis-à-vis and one of said outer peripheral edges may be formed by the periphery or the end 3b of the receiving surface 3a. The passage slot also makes it possible, when stopping the supply of the liquid, to immediately stop the diffusion of the droplets by keeping the liquid by capillary action inside the secondary internal space 5b, a capillarity effect essentially generated 30 by the proximity of the peripheral edges of the passage slot 5c at the side surface 5a of the fuselage. It allows in fact, as soon as the supply of liquid returns the generation of droplets by centrifugal effect at the end 3b of the receiving surface 3a. In this first embodiment of the fuselage 5, the rotary atomizer 3 may have an ogival or conical or frustoconical shape with an outer end face that may be located in a plane substantially perpendicular to the longitudinal axis X of the nozzle 1 and can be turned towards the inlet opening 1a of the nozzle 1. Such an outer end face may form the receiving surface 3a of the rotary atomizer. In a second embodiment of the fuselage 5, as can be seen in FIG. 5, the receiving surface 3a of the rotary atomizer 3 may be located outside the secondary internal space 5b. More particularly, the distal end of the fuselage 5 can end with an outer end face extending in a plane substantially perpendicular to the longitudinal axis of the nozzle 1 and being turned towards the air outlet opening 1b. . Such an outer end face may form the receiving surface 3a of the rotating atomizer 3 (FIG. 5). In this case, the secondary internal space 5b may be empty, partially empty or full. As can be seen in particular in FIGS. 3, 4a, 4b and 5, the fuselage 5 can comprise a lateral liquid supply extension 5d which can advantageously have an aerodynamic profile and in which a feed channel can be made. liquid which may at least partly form the main supply conduit 8. In addition, the lateral liquid supply extension 5d may extend transversely, preferably perpendicularly, to the longitudinal axis 20 of the nozzle 1 in the annular channel for circulating the flow of carrier air. As can also be seen in FIG. 12, the spraying unit may furthermore comprise electrical wires 6 making it possible to supply electrical power to the or each electric motor 4 and the fuselage 5 may comprise a lateral power supply extension. 25 5th may advantageously have an aerodynamic profile. In addition, the lateral power supply extension 5e may extend transversely, preferably perpendicularly, to the longitudinal axis X of the nozzle 1 and may be traversed by a power supply channel 50c forming a passage for the wires 6 in the annular channel of circulation of the flow of carrier air. In the case where the spraying unit comprises a lateral liquid supply extension 5d, the lateral power supply extension 5e may be provided so as to be diametrically opposed to the lateral liquid supply extension 5d. On the other hand, if one refers to FIGS. 2, 3, 4a, 4b, 5, it can be seen that, so as to be able to straighten the flow of carrier air, having a helical shape at the exit of the helix 2a, in the axis of the nozzle 1 before contact with the droplets, the present invention can provide that the spray unit may further comprise a rectifier device 14 extending into the annular circulation channel of the nozzle. carrier air flow and can be arranged axially between the fan 2 and the rotary atomizer 3. Preferably the rectifier device 14 can be located near the fan 2. Thus, with such a rectifier device, it is possible to obtain downstream of the latter, a coherent carrier air flow organized in speed and direction substantially in the axis of the nozzle 1 in a non-laminar manner for better energy efficiency before contact with the droplets.
[0012] Such a rectifier device 14 may comprise a plurality of rectifying elements 14a such as vanes, each blade 14a being able to extend between two end edges one of which may be fixed on the fuselage 5, that is to say ie on the outer face of its surface, or side wall 5a, and the other may be fixed on the nozzle 1, that is to say on the inner face of the latter. The assembly or the plurality of rectifying elements 14 may be made in one piece, for example in combination with a portion of the nozzle and part of the fuselage wall 5a. In an advantageous embodiment, as in FIG. As can be seen in particular in FIG. 12, the rectifier device 14 may comprise the lateral liquid supply extension 5d and / or the lateral power supply extension 5e. Where appropriate, as can be seen in this figure 12, one of the rectifier elements 14a may include the lateral power supply extension 5e and / or the lateral liquid supply extension 5d.
[0013] On the other hand, referring again to FIGS. 2, 3, 4a, 4b, 5, it can be seen that the spray unit may further comprise a diffuser device 15 extending into the annular flow channel of the flow. carrier air and that the diffuser device 15 can be arranged axially between the fan 2 and the rotary atomizer 3, preferably close to the receiving surface 3a. In a preferred embodiment (FIGS. 2, 3, 4a, 4b, 5), the diffuser device 15 may comprise at least three diffusing elements 15a, 15b, one of which, said central diffuser 15a, may consist of a hollow part central generally cylindrical or frustoconical 35 surrounding the fuselage 5, while the other diffuser elements, said lateral diffusers 15b, preferably two other diffuser elements, may each have an aerodynamic wing shape extending transversely to the axis of said diffuser element 15a and be fixed on the outer lateral face of the central diffuser 15a, preferably being distributed diametrically opposite. Such a diffuser device 15 has the effect of arranging, in conjunction with the air outlet opening 1b of the nozzle 1, the mixture of the droplets coming from the rotary atomizer 3, in particular from its reception surface 3a. maintaining the characteristics of the coherent and nonlinear carrier air stream from the fan 2 and the rectifying device 14, and uniformly carrying them in the form of a brush at the target (for example vegetation ). Fixing and holding the diffuser device 15 can preferably be achieved by fixing it, for example by means of the wing-shaped diffuser elements 15b, on the internal face of the nozzle 1 and / or on the face external of the fuselage 5 (Figures 2, 3, 4a, 4b, 5).
[0014] Such a spraying unit makes it possible to obtain an efficient combination of the injection of the droplets, preferably in a direction in a substantially vertical plane or projection surface (e) to the longitudinal axis X of the nozzle 1, in a flow of carrier air with a high speed and adapted. Indeed, if the speed of the carrier air flow is too low, a portion of the droplets can be projected onto the inner wall of the nozzle 1 which generates a dripping and a loss of liquid towards the target 21 and if the speed the carrier air flow is too high, the brush formed by it at the outlet of the nozzle 1 is then too focused and narrow, which does not allow a mixture of droplets throughout the air flow at the outlet of 25 nozzle 1. In the present invention, the droplets are projected into the flow of carrier air inside the nozzle 1, that is to say in its main space lc, so that their diffusion in the flow of carrier air is not disturbed by the external atmosphere unlike for example the system described in US6152382.
[0015] The present invention also relates to a compact spray module for spraying a liquid in the form of droplets for treating a target 21, such as for example a plant hedge. According to the invention, such a module, as can be seen in particular in Figures 1, 2, 8, 9 and 10 comprises: - a spray unit according to the invention as described above, 3037826 -24- - its own liquid supply system 7, 11 operably connected to the conveying means 8, 9 of said spraying unit, said supply system comprising an electric pump 11 for discharging, with a controlled variable flow, the liquid , coming from a reservoir 26, in said conveying means and a hydraulic connection interface 7 allowing said system to receive the liquid coming from the reservoir 26, a support 10 making it possible to fix the electric pump 11 close to the sputtering unit; an electronic control and / or control unit 17, for example implanted on an electronic card, for controlling and / or controlling the operation of the system; 4a, 4a and the liquid supply system being operably connected to said drive and liquid supply systems, an electrical connection interface 20 'for connection of the drive system 4, 4a, the liquid supply system, including the electric pump 11 and the electronic control unit and / or control 17 to an electrical power source 22 to ensure their power supply.
[0016] The reservoir 26 is located, preferably, outside and at a distance from the module, for example by being mounted on a machine or a mobile machine 23 supporting at least one module according to the invention (FIG. 10). The spraying unit, more particularly via the nozzle 1, can be fixed on the support 10. Such a support 10 can be made in two parts, for example generally semi-cylindrical, assembled one to the other. another so as to allow easy mounting and disassembly of the support 10 and parts of the modules fixed, if necessary removably, to the latter.
[0017] The electric pump 11, possibly associated with a flow sensor, is capable of delivering, under the control and / or control of the electronic control and control unit 17, via the conveying means 8, 9 a controlled variable flow rate at the rotary atomizer 3 and may preferably consist of a positive displacement pump, more preferably a peristaltic pump. The advantages of a positive displacement pump, and in particular of a peristaltic pump, are to deliver a precise liquid flow rate dependent on the speed of rotation of the pump under a pressure that is little different from or substantially equal to the atmospheric pressure and without the assistance of a flow sensor. Thus, the stop in instantaneous rotation of the pump, does not generate residual pressure in the downstream circuit thus avoiding the inadvertent flow of liquid at the rotary atomizer 3. Similarly, the accuracy obtained by this type of pump avoids positioning an additional flow sensor in the supply system. And finally, the range of possible rotational speed of the pump leads to the possibility of varying its flow in a large range. In this case, a flow setpoint can be supplied to the peristaltic pump by software or an operator and can be translated directly into the rotational speed reference of the peristaltic pump. Referring to FIG. 11, the electronic control and / or control unit 17 may comprise a microprocessor and a memory which may contain codes representative of the spraying parameters to be adjusted and / or a code of identification of said module, as well as an internal communication bus to the members of the module (liquid supply system, drive system with an electric motor, etc.). The microprocessor of the control and control unit 17 may be provided to determine at least one of the following control information: - temperature information and / or current / voltage information and / or speed information relating to the operation of the electric motor drive system 4, 4a (fan and / or rotary atomizer), temperature information and / or current / voltage information and / or relative speed information ( s) to the operation of the electric pump 11, - information relating to the identification code Id of said spray module.
[0018] The microprocessor can also be provided to receive at least one of the following setpoint information from the control electronic central unit 13: a setpoint information relating to the operation of the drive system 4, 4a, 35 set point relative to the operation of the electric pump 11. In a preferred use and in a preferred embodiment of such a module, it can be provided to be connected in a spray and control system comprising a plurality of spray modules and a control panel 16 (FIGS. 10, 11). For this purpose, the module may furthermore comprise an individual communication interface 20 making it possible to connect the control and / or electronic control unit 17 to the control panel 16 via a communication bus 25, in order to to allow, from the latter, individual remote control of said module, 10 independently of the other modules, to be able to instantly adapt at least one spray parameter. The connection means 6, which may comprise electrical wires, may be provided to functionally connect the electronic control and / or electronic control unit 17, the drive system 4, 4a and the electric pump 11, by the intermediate of the electrical connection interface 20 ', the source of electrical energy 22 via an electrical network 30. On the other hand such connection means 6 may also include electrical son to connect functionally the electronic control and / or control unit 17, via the individual communication interface 20, to the control panel 16. Preferably, as can be seen in FIGS. 1, 2, 9 and The electrical connection interface 20 'and the individual communication interface 20 may be located at the same point in the module, for example in the form of a multi-channel connector. s. The individual communication interface 20 may also be provided to include a radio frequency transmission circuit for radio frequency transmission of the communication signals necessary for the operation of the module. The spray module according to the invention may comprise a housing 19, for example in the form of a housing, adapted to receive and house the control and / or electronic control unit 17 and, where appropriate, the interface Communication. In addition, the housing 19 can be mounted on the nozzle 1 or integrated in the latter (see in particular Figures 1, 2, 3, 4a, 4b, 5, 12). The spray module according to the invention may further comprise a housing which can receive and house the spray unit. On the other hand, such a housing may also be provided to form the support 10 for the electronic pump 11 (Figures 1, 2, 8, 9, 10).
[0019] With reference in particular to FIGS. 1, 2, 3, 4a, 4b, it can be seen that the housing 10 can be fixed, for example, on the nozzle 1, for example by snapping or engaging. For this purpose, the housing 10 may have a generally cylindrical shape whose open ends each comprise an internal rib 10a generally circular or oval and the nozzle 1 may comprise at each of its ends a ld globally circular or oval groove adapted to receive by snap or interlocking one of the internal ribs 10a. The casing 10 can be made in two half-shells. The two half-shells can be further connected together by screwing.
[0020] Referring now to FIGS. 10 and 11, it can be seen that another object of the invention is a spray and control system intended to be loaded onto a machine or mobile machine 23, said system comprising a plurality of modules spraying method for spraying a liquid in the form of droplets 18 for the treatment of a target such as, for example, a plant hedge 21, said liquid coming from a reservoir. According to the present invention, such a spray and control system further comprises a control panel 16 comprising an electronic control unit 13 and a man-machine interface 16a, called the HMI, connected to the latter, each spray module consisting of a compact spray module as defined according to the present invention. Still in accordance with the present invention, the electronic control unit 13 is operatively connected to each spray module so as to allow individual remote control of each spray module, independently of the other spray module or modules, from said control panel to individually adjust the spraying and operating parameters of each spray module.
[0021] Among the spraying parameters, the invention can provide, for example: the flow of liquid transformed into droplets by the rotary atomizer 3 during the rotation of its reception surface 3a, the size of the droplets, the speed of the carrier air flow carrying said droplets on the target. The GUI 16a may comprise a display screen 160a intended to visually display at least one of the control information and / or at least one of the setpoint information as defined above, so as to be able to control and monitor in real time the operation of each spray module directly from the control panel 16. For example, such a display screen can display the air velocities and the amount of liquid sprayed by the modules of spray. The HMI 16a may also include 160b devices 15 such as a joystick and / or push buttons allowing the user to carry out various commands, adjustments or controls of the system, for example the setting of a manual or automatic mode of the system, adjusting the flow rate of the liquid to be sprayed from said selected spray module or the setting of the row width by selecting depending on this width the number of spray module to start. More particularly, the central control unit 13 and the control and / or electronic control unit 17 of each module can be configured to be able to adapt, instantaneously, on the one hand, the quantity of droplets and the flow rate. of the electric pump 11 controlling the operation of the latter and, secondly, the size of the droplets and / or the speed of the latter and / or the air speed at the outlet of the nozzle 1 by controlling and controlling the operation of the drive system 4, 4a for regulating the rotational speed of the receiving surface 3a of the atomizer 3 and / or the speed of rotation of the fan 2a 2a. This allows in particular to adapt the parameters spraying the liquid, such as mud, both as a function of the target, such as vegetation, encountered in the direction of movement of the machine or mobile machine 23 carrying such a module 35 but also, at a given moment born, along a spray boom with several modules according to the target positioned next to each module. At each instant the regulation of the spraying parameters of the liquid allows either the instantaneous stopping of one of the parameters of the module (immediate for the pump, of the order of one to two seconds for the propeller), either the instantaneous activation of at least one of these parameters (less than one second to restart the helix and generate the desired flow of carrier air, instantaneous start-up of the pump at the desired speed of rotation and therefore at the desired rate) so as to generate on the target a homogeneous treatment brush, the brushes of each module overlapping very slightly to ensure the treatment of the entire plant cover facing the module ramp.
[0022] In such a spraying system, the electronic control and / or control unit 17 of each module can be adapted to control and / or control the drive system 4, 4a with electric motor (s) and the electric pump 11 from control signals sent by the central unit 13 via the communication interface to the control unit 15 and / or electronic control 17 concerned individual (Figure 11). Such a spray and control system may be equipped with at least one spray boom forming a support integral with the machine or mobile machine 23 and being designed to carry a plurality of modules (FIGS. 8 and 10). On the other hand, as can be seen in FIG. 11, such a spraying and driving system according to the present invention may comprise a central communication bus 25 making it possible to connect each spray module functionally to the central unit 13.
[0023] As can be seen again in FIG. 11, such a spraying and control system may further comprise a detection system 24 operatively connected to the central unit 13, where appropriate via the central communication bus. 25 or by radio frequency. The detection system 24 can be adapted to detect an absence or a presence of the target 21 and / or a target profile and to transmit to the central unit 13 information relating to said detection so as to perform the individual control of each spray module according to said detected information. In such a spraying system, the CPU 13 may comprise a communication gateway operably connected to the central communication bus 25 and each sputtering module may be operably connected thereto so as to allow the unit 3037826 - 30 central unit 13 to remotely control each spray module via said central communication bus 25. More particularly, the detection system 24 may comprise presence detection means 24a, such as for example one or more ultrasonic sensors, infrared, lasers ..., for detecting the presence or absence of the target 21 and being adapted to transmit to the central unit 13 a signal representative of this detection, said central unit 13 being adapted to control according to this detection, at least one of the spray modules by controlling and controlling either the start, respectively stopping the operation of its own electric pump 11 and / or its drive system 4, 4a. It may also comprise target profile detecting means 24b making it possible to detect a physical quantity providing information on the profile of the target 21, such as its surface area or its density, and being adapted to transmit to the central unit 13 a signal representative of this information, said central unit 13 being adapted to individually control each spray module according to this information by controlling and controlling the operation of the electric pump 11 to adjust the flow rate of the liquid supplying the rotary atomizer 3 20 and / or the operation of the drive system 4, 4a to adjust the airflow velocity and / or the operation of the rotary atomizer 3 to adjust the size of the droplets and / or the airflow velocity. The detection system 24 may include both such presence detection means and such target profile detection means. Thus, such a spray unit or such a module or such a spray system, according to the invention, can spray, from one or more spray units or modules, dynamically, a liquid in the form droplets 18 in appropriate size and quantity and mixed with an undisturbed carrier air flow capable of sweeping the target, in particular the vegetation, located at a distance opposite the air outlet opening, in the form of a homogeneous paintbrush of liquid droplets. The size and the quantity of droplets can thus be adapted according to the nature of the liquid sprayed, the volume of plant to be treated, the age and the type of vegetation located in the treatment brush of the module, while limiting the projections outside the vegetation to be treated and without structural modification of the module passing from one type of vegetation to another or from one treatment product to another. The liquid flow, the size of the droplets, and the speed of the carrier air flow can thus be modified instantaneously, remotely and, where appropriate, differently from one module to another in a system 5 according to the invention. the invention, without direct human intervention on the module, the changes being controlled remotely and instantly by the operator of the machine or automatically. Such a system makes it possible to reduce as much as possible the quantity of product (the liquid) applied to the target 21, such as a vine, by essentially distributing it on the latter and makes it possible, for example, to provide, for example, at least one product. one of the following functionalities and advantages: - adjustment of the spraying parameters on the control console 16 from the cab of the mobile machine 23, eliminating the contact 15 between the user and the phytosanitary product (liquid), - setting on the control panel 16 of the target type, the row width and the theoretical product flow to be sprayed per unit area and / or the selection of the product to be sprayed, the system having in memory the approved doses of this product, - Adjustment of the flow rate and the row width on the control panel 16 in order to automatically change the spraying parameters during treatment, - Variations in the flow rate of the electric pump 11 proportion the speed of advance of the mobile machine 23, 25 - instantaneous manual and / or automatic adjustment of the flow rate, the air velocity or the size of the droplets on each spray module in order to optimize the application liquid 18 on the target 21, - automatic detection of the target in order to trigger and stop the spraying when the system detects the target 21 (for example 30 of the vegetation) at the entry of rank or during rank or detects more target 21 in the row or at the end of the rank, - allow the user to correlate the information displayed on the control panel 16 with the quantity of liquid 18 (slurry) prepared at the beginning of treatment in order to verify that the a good quantity of product has been applied to the target, - monitor and follow in real time the spraying and piloting system making it possible to know, for example, the electrical consumption of each module of the rotation speed of each electric pump 11, the real-time verification of the communication between the control panel 16 and the spray modules, 5 - allow the system to be diagnosed from the control panel 16, and therefore for example from the cab of the mobile machine 23 where the console is located, and the operation before and during the treatment to immediately detect any malfunction that may affect the quality of treatment, 10 - simplify the calibration of the electric pumps 11 of each module , so as to allow each electric pump 11 to be adjusted as precisely as possible by applying a correction factor to the electric pump 11 directly from the control panel 16. The electronic control unit 13 of the control panel 16, which may include a microprocessor, may be provided to be automatically controlled by a program or software . On the other hand, the electronic control and control unit 17 of each module, and in particular the microprocessor of each module, can be provided to be controlled automatically by a program or software.
[0024] In addition, the electronic control unit 13 and / or the control unit and each electronic control and control unit 17 may be provided to allow an updated update of the programs or software. Such updating of the program or software stored in a memory of the electronic control central unit 13 can be carried out from the control panel 16. The update of the program or software stored in a memory of the unit electronic control and control 17 of each module can be carried out directly in the latter or from the control panel 16 via the corresponding communication interface 20.
[0025] It will be understood that the operations performed by the spray modules can be manually controlled by the operator from the control panel 16 or, if appropriate, automatically by the program or software provided for this purpose and can be activated automatically, for example following detection by the aforementioned detecting means. Of course, the invention is not limited to the modes or embodiments described and shown in the accompanying drawings. Modifications are possible, especially from the point of view of the constitution of the various elements or by substitution of technical equivalents, without departing from the scope of protection of the invention.

权利要求:
Claims (30)
[0001]
CLAIMS1) A spraying unit for spraying a liquid in the form of droplets (18) for the treatment of a target (21), such as for example a vegetable hedge, said spraying unit comprising a nozzle (1) formed by a duct extending along a longitudinal axis (X) internally defining a main internal space (1c) and being open at its ends to form an air inlet opening (1a) and an outlet opening (1c); air (1b), the main internal space (1c) receiving at least one rotary atomizer (3) rotatably mounted about a first axis of rotation (X1), conveying means (8, 9) for conveying the liquid, from a supply system with controlled variable flow, to the rotary atomizer (3), a fan (2) having at least one propeller (2a) rotatably mounted about a second axis of rotation (X2) and for generating a flow of carrier air in the inner internal space cipal (lc) to and beyond the air outlet opening (1b) and a drive system (4, 4a) with electric motor (s) to provide rotational drive said rotary atomizer and propeller, said rotary atomizer (3) comprising a receiving surface (3a) adapted to receive the liquid and for ensuring, at its periphery or end (3b), the rotational state of said rotary atomizer, the fragmenting the liquid into droplets (18) and propelling them into the flow of carrier air, and connecting means (6) to an electric power source (22) for supplying electrical energy to the drive system (4). , 4a), spray unit characterized in that it further comprises an inner fuselage (5) having an airfoil defined by a lateral surface (5a) internally delimiting a secondary internal space (5b) and being held axially in the main internal space (lc) between the fan (2) and the air outlet opening (1b) so as to define, between the fuselage (5) and the nozzle (1), an annular channel for circulating the flow of carrier air surrounding said fuselage, in that the fuselage (5) comprises a rotary section formed by the rotary atomizer (3) so that the periphery or the end (3b) of the receiving surface (3a) is substantially in the lateral surface of the fuselage (5) while by allowing rotation of the rotary atomizer (3) and propulsion, preferably substantially perpendicular to the longitudinal axis (X), droplets in said channel to be incorporated in the air stream.
[0002]
2) Spray unit, according to claim 1, characterized in that the respective first and second axes of rotation (X1, X2) of the rotary atomizer (3) and the propeller (2a) are substantially merged or merged. between them, preferably substantially merged or confused with the longitudinal axis (X) of the nozzle.
[0003]
3) Spray unit, according to any one of claims 1 to 2, characterized in that the drive system (4, 10 4a) is housed in the secondary internal space (5b) of the fuselage (5).
[0004]
4) Spray unit, according to one. any of claims 1 to 3, characterized in that the drive system (4) comprises at least one electric motor (4) and at least one drive shaft (4a) for rotating the atomizer 15 rotating (3) about the first axis of rotation (Xl) and the helix (2a) about the second axis of rotation (X2).
[0005]
5) Spray unit according to claim 4, characterized in that the drive system comprises a single common electric motor (4) and a single common drive shaft (4a) rotated about its axis (X1). , X2) by said electric motor, said electric motor and said common drive shaft to ensure both the rotation of the helix (2a) about the second axis of rotation (X2) and the rotation of the atomizer rotatable (3) about the first axis of rotation (X1), said first and second axis of rotation (X1, X2) being merged therebetween.
[0006]
6) Spray unit according to claim 4 or claim 5, characterized in that the fuselage (5) comprises at least one cooling section surrounding the electric motor or motors (4) and being in contact with the air flow. carrier for discharging by said contact a portion of the heat generated by the one or more electric motors, said section being made of aluminum.
[0007]
7) Spray unit according to any one of claims 1 to 6, characterized in that the receiving surface (3a) of the rotary atomizer (3) extends in a plane substantially perpendicular to the longitudinal axis. (X) of the nozzle (1). 3037826 - 36 -
[0008]
8) Spray unit, according to claim 7, characterized in that the rotary atomizer (3) has generally a form of disk or frustoconical or conical piece and that one of the outer faces of the disk or the workpiece frustoconical or conical forms the receiving surface 5 (3a).
[0009]
9) Spray unit according to any one of claims 1 to 8, each taken in combination with claim 4 or claim 5, characterized in that the rotary atomizer (3) is pierced centrally and axially by a bore (3c ) allowing the passage of the drive shaft (4a) allowing its rotation about the first axis of rotation (X1) via a drive link.
[0010]
10) Spray unit according to any one of claims 1 to 9, characterized in that the conveying means (8, 9) comprise a main supply duct (8) intended to receive the liquid coming from a liquid supply system (7,
[0011]
11) and for supplying, directly or indirectly, at least one feed point, the rotatable receiving surface (3a) and in that the fuselage (5) comprises a lateral liquid supply extension (5d) having a aerodynamic profile and in which passes at least a portion of the main supply duct (8) integrated or reported in said extension extending transversely to the longitudinal axis of the nozzle (1) in the annular channel flow circulation carrier air. 11) Spray unit according to claim 10, characterized in that the main supply duct (8) is provided for supplying liquid indirectly to the receiving surface (3a), in that the conveying means (8) ) furthermore comprise for this purpose at least two secondary supply ducts (9) each intended to be connected to said main supply duct (8) and to be located in the secondary internal space (5b) of the fuselage (5) and in that it further comprises an intermediate feed and distribution piece (12) comprising the secondary feed duct or ducts (9) and being arranged in the secondary internal space (5b) of the fuselage (5) between, on the one hand, the fan (2), where appropriate the electric motor (4), and, on the other hand, the rotary atomizer (3), in close proximity to the latter so that each duct secondary supply (9) opens out of the carrier air flow in re guard and in the immediate vicinity of its rotary reception surface (3a) to supply liquid at at least two feed points, preferably distributed on either side of the first axis of rotation (X1). , where appropriate on either side of the drive shaft (4a) for rotating the receiving surface (3a) about said first axis of rotation (X1). 5
[0012]
12) Spray unit, according to claim 11, characterized in that the intermediate feed and distribution member (12) comprises an annular groove (12a) for distributing the liquid having at least two orifices (12b) each opening into the one of the secondary supply ducts (9) and in that the main supply duct (8) is provided to open into the annular groove (12a) which thus ensures the distribution of the liquid, conveyed from the electric pump ( 11) through the main supply duct (8) into the secondary supply ducts (9).
[0013]
13) A spraying unit according to claim 12, characterized in that the intermediate feed and distribution piece (12) has a generally cylindrical shape and is pierced at one of its end faces, for example turned to the outlet or air inlet opening (1a, 1b) of the nozzle (1), by at least two feed holes (12d) respectively forming the liquid feed points, the annular groove (12a) being formed in the outer side face of said feed and distribution part and the secondary supply ducts (9) being formed in the material of the intermediate feed and distribution piece (12) of so as to open at one of their ends in the annular groove (12a) and at their other end in one of said feed holes and in that the fuselage (5) is designed in its part receiving said intermediate piece of Food processsing and distribution (12) to surround said annular groove by providing a fluid seal with the latter.
[0014]
14) Spray unit according to any one of claims 11 to 13 taken in combination with any one of claims 4 to 5, characterized in that the intermediate feed and distribution piece (12) is traversed axially by a through bore (12c) allowing passage of the drive shaft (4a) rotating the rotary atomizer (3). 35
[0015]
15) Spray unit, according to any one of claims 1 to 14, characterized in that the fuselage (5) comprises two ends, one of which, said distal end, is furthest from the fan (2). ) and that the rotating portion of the fuselage (5) forms said distal end.
[0016]
Spray unit according to one of claims 1 to 15, characterized in that the receiving surface (3a) of the rotary atomizer (3) is located in the secondary internal space (5b) and the axial or longitudinal continuity of the lateral surface (5a) of the fuselage (5) is interrupted by a transverse passage slot (5c) allowing the droplets to be propelled into the flow of carrier air through the lateral surface (5a) of the fuselage ( 5), said passage slot being delimited by two outer peripheral edges vis-a-vis of which one of these is formed by the periphery or the end (3b) of the receiving surface (3a).
[0017]
17) Spray unit according to claim 15, characterized in that the distal end of the fuselage ends in an outer end face extending in a plane substantially perpendicular to the longitudinal axis of the nozzle and being rotated to the air outlet opening (1b), said outer end face forming the receiving surface (3a) of the rotary atomizer (3).
[0018]
18) A spray unit according to any one of claims 1 to 17, characterized in that the fuselage (5) comprises a lateral liquid supply extension (5d) having an aerodynamic profile and in which a channel is formed. supplying the liquid at least partly forming the main supply duct (8), said extension extending transversely to the longitudinal axis of the nozzle (1) in the annular channel for circulating the carrier air flow. 25
[0019]
19) Spray unit, according to any one of claims 1 to 18 taken in combination with any one of claims 4 to 5, characterized in that it further comprises electrical son (6) for supplying power. the electric motor or each electric motor (4) and that the fuselage (5) comprises a lateral power supply extension (5e) having an aerodynamic profile and extending transversely to the longitudinal axis (X) of the nozzle (1) and being traversed by an electrical supply channel (50e) forming a passage for said electrical wires (6) in the annular channel for circulation of the carrier air flow, if appropriate, said lateral extension 35 of power supply (5e) being possibly diametrically opposed to the lateral liquid supply extension (5d). 3037826 39 -
[0020]
20) Spray unit, according to any one of claims 1 to 19, characterized in that it further comprises a rectifier device (14) extending in the annular channel for circulating the flow of carrier air and being arranged axially between the fan (2) and the rotary atomizer (3) so as to be able to straighten the flow of carrier air before contact with the droplets, preferably said rectifier device being located near the fan (2).
[0021]
21) Spray unit according to claim 20, characterized in that the rectifying device comprises a plurality of rectifying elements such as blades (14), each blade (14) extending between two end edges of which one is fixed on the fuselage (5) and the other is fixed on the nozzle (1).
[0022]
22) Spray unit according to any one of claims 1 to 21, characterized in that it further comprises a diffuser device (15) extending in the annular channel for circulating the flow of carrier air and said diffuser device (15) is arranged axially between the fan (2) and the rotary atomiser (3), preferably close to the receiving surface (3a) thereof.
[0023]
23) A spray unit according to claim 22, characterized in that the diffuser device (15) comprises three diffuser elements, one of which (15a) consists of a central hollow part of frustoconical shape, while the other two elements diffusers (15b) each have an aerodynamic wing shape extending transversely to the axis of said frustoconical diffuser element (15a) and are each fixed on the external face 25 of revolution of the latter, preferably being distributed diametrically opposite, said wing-shaped diffuser elements (15b) being fixed to the nozzle (1).
[0024]
24) Spray unit according to claim 18 and / or claim 19 taken in combination with any one of claims 20 to 21, characterized in that the rectifying device as defined in claim 20 is formed by the lateral liquid supply extension as defined in claim 18 and / or the lateral electrical supply extension as defined in claim 19.
[0025]
25) Spray unit, according to any one of claims 1 to 24, characterized in that the air outlet opening (lb) has an oval shape. 3037826 - 40 -
[0026]
26) Compact spray module for spraying a liquid in the form of droplets for the treatment of a target (21), such as for example a vegetable hedge, characterized in that it comprises: a spray unit such as As defined in any one of claims 1 to 25, its own liquid feed system (7, 11) operatively connected to the conveying means (8, 9) of said spray unit, said dispensing system, supply comprising an electric pump (11), preferably a positive displacement pump, more preferably a peristaltic pump, optionally associated with a flow sensor, for discharging, with a controlled variable flow, the liquid from a reservoir (26), in said conveying means and a hydraulic connection interface (7) allowing said supply system to receive the liquid from the reservoir (26), - a support (10) enabling to firmly hold the electric pump (8) close to the spraying unit, - an electronic control and / or control unit (17), for example implanted on an electronic card, designed to control and / or control the operation of the drive system (4, 4a) and the liquid supply system (7, 11), said electronic control and / or control unit being operably connected to said drive and liquid supply systems ( 4, 4a; 7, 11), - an electrical connection interface (20) for connection of the drive system (4, 4a), the electronic control and / or control unit (17) and the power supply system. in liquid to a source of electrical energy (22) to ensure their power supply.
[0027]
27) Spray module according to claim 26, characterized in that it is intended to be connected in a spraying and control system comprising a plurality of spraying modules and a control panel (16) and in that it furthermore comprises for this purpose a communication interface (20) making it possible to connect the control and / or electronic control unit (17) to the control console (16), in order to allow individual remote control. said module, independently of other modules, to instantly adapt at least one spray parameter. 3037826 - 41 -
[0028]
28) Spray module according to claim 26 or claim 27, characterized in that it comprises a housing (19) adapted to receive the control unit and / or electronic control (17) and, where appropriate, the communication interface (20), and in that said housing 5 is mounted on the nozzle (1) or integrated therein.
[0029]
29) spray module according to any one of claims 26 to 28, characterized in that it further comprises a housing (19) housing the spray unit and forming the support for the electronic pump (11). 10
[0030]
30) Spraying and control system intended to be carried on a machine or mobile machine (23), said system comprising a plurality of spray modules for spraying a liquid in the form of droplets (18) for the treatment of a target such as, for example, a plant hedge (21), said liquid coming from a reservoir, characterized in that it further comprises a control console (16) comprising an electronic control central unit (13) and a man-machine interface (16a), called the HMI, connected to the latter, each spray module consisting of a compact spray module as defined in claim 27 and according to any one of claims 28 to 29, each taken in combination with claim 27 and in that the electronic control unit (13) is operatively connected to each spray module so as to allow individual control to be provided. each of said spray modules, independently of the one or more other spray modules, from said control panel to individually adjust the spray and operating parameters of each spray module.

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BE536471A|

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同族专利:

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公开号 | 公开日

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AU2016283022A1|2018-01-04|

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CN107771104B|2021-03-09|

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EP3313581A1|2018-05-02|

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BR112017027570A2|2018-08-28|

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CN107771104A|2018-03-06|

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US10555517B2|2020-02-11|

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AU2016283022B2|2021-05-13|

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ES2772681T3|2020-07-08|

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NZ738175A|2021-06-25|

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WO2016207571A1|2016-12-29|

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US20180160670A1|2018-06-14|

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CL2017003289A1|2018-07-06|

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EP3313581B1|2019-11-13|

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JP2018520857A|2018-08-02|

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ZA201708280B|2020-09-30|

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FR3037826B1|2019-09-20|

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法律状态:
2016-04-21| PLFP| Fee payment|Year of fee payment: 2 |

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2016-12-30| PLSC| Search report ready|Effective date: 20161230 |

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2017-04-28| PLFP| Fee payment|Year of fee payment: 3 |

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2018-05-18| PLFP| Fee payment|Year of fee payment: 4 |

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2019-05-21| PLFP| Fee payment|Year of fee payment: 5 |

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2020-06-11| PLFP| Fee payment|Year of fee payment: 6 |

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2021-06-22| PLFP| Fee payment|Year of fee payment: 7 |

优先权:

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申请号 | 申请日 | 专利标题

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FR1555894|2015-06-25|

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FR1555894A|FR3037826B1|2015-06-25|2015-06-25|SPRAY UNIT, COMPACT SPRAY MODULE COMPRISING SUCH A UNIT AND SPRAY AND PILOTAGE SYSTEM COMPRISING A PLURALITY OF SUCH MODULES|FR1555894A| FR3037826B1|2015-06-25|2015-06-25|SPRAY UNIT, COMPACT SPRAY MODULE COMPRISING SUCH A UNIT AND SPRAY AND PILOTAGE SYSTEM COMPRISING A PLURALITY OF SUCH MODULES|

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US15/739,225| US10555517B2|2015-06-25|2016-06-24|Spraying unit, compact spraying module including such a unit, and spraying and control system including a plurality of such modules|

---

EP16741103.2A| EP3313581B1|2015-06-25|2016-06-24|Spraying unit, compact spraying module including such a unit, and spraying and control system including a plurality of such modules|

---

AU2016283022A| AU2016283022B2|2015-06-25|2016-06-24|Spraying unit, compact spraying module including such a unit, and spraying and control system including a plurality of such modules|

---

NZ738175A| NZ738175B2|2015-06-25|2016-06-24|Spraying unit, compact spraying module including such a unit, and spraying and control system including a plurality of such modules|

---

BR112017027570-8A| BR112017027570A2|2015-06-25|2016-06-24|spray unit, compact spray module including such unit, and spray and control system including a plurality of such modules|

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PCT/FR2016/051561| WO2016207571A1|2015-06-25|2016-06-24|Spraying unit, compact spraying module including such a unit, and spraying and control system including a plurality of such modules|

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CN201680035222.4A| CN107771104B|2015-06-25|2016-06-24|Spraying unit, compact spraying module comprising such a unit and spraying and control system comprising a plurality of such modules|

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ES16741103T| ES2772681T3|2015-06-25|2016-06-24|Spraying unit, compact spraying module including said unit, and spraying and control system including a plurality of said modules|

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JP2017566653A| JP2018520857A|2015-06-25|2016-06-24|Spray unit, compact spray module comprising such a spray unit, and spray and steering system comprising a plurality of such modules|

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ZA2017/08280A| ZA201708280B|2015-06-25|2017-12-06|Spraying unit, compact spraying module including such a unit, and spraying and control system including a plurality of such modules|

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CL2017003289A| CL2017003289A1|2015-06-25|2017-12-20|Spray unit, compact spray module that includes said unit, and spray and control system that includes several of said modules|