FR2920101A1 - Solid e.g. powder, type phytosanitary product dosing device for e.g. sprayer in agriculture, has homogenizer mixer comprising outlet provided in lower part of tank and connected to mixture spraying pump - Google Patents

Abstract

The device has a dosing unit for dosing a solid phytosanitary product found in a tank (16) made of synthetic material, and a homogenizer mixer (23) with an injection conduit (17) in which water and dosed product are introduced. The mixer has an outlet provided in a lower part of the tank and connected to a mixture spraying pump (11). A booster pump (3) sucks the water from a transport tank (1) and injects a quantity of the desired water in the injection conduit by a passage (30) and using a control of a control valve (4).

Description

The present invention relates to a device for assaying

  phytosanitary products in solid form. Phytosanitary products are mainly in liquid form or in solid form. In the latter case, it is usually a question of powders or granules. Most often, in agriculture, plant protection products are spread in liquid form by means of a sprayer. The latter then sprays a mixture of water and phytosanitary product. When the product to be sprayed is in liquid form, an injection system ensures accurate dosing of the product in the water and this mixture is sent by a pump to a spray boom. When the product to be sprayed is in solid form, it is either mixed with water directly into the spray tank, or it is mixed with a small amount of water to form a slurry which can then be metered in a injection system for dosing liquid crop protection products. Mixing powders or granules in a tank poses various problems. When spraying, if there is product in the tank, it can hardly be stored until next use. Most often, this product is thrown away. Since these products are active products, their release poses ecological problems. Then this rejection is a waste of money for the farmer. Similarly when a slurry has been formed, there are the same problems because it is not possible to store the product as a slurry. Direct injection systems for the dosing of liquid products in spraying systems make it possible to recover unused liquid products at the end of spraying and thus solve the problems mentioned above for products in solid form. Good management of the rinsing procedure also limits the release of pesticides at the end of the spray. The purpose of the present invention is therefore to provide a dosing system for phytosanitary products in solid form which makes it possible, at the end of the spraying operation, to recover the unused product. Of course, this system will preferably allow a precise dosage of products and will adapt to products in different forms with also different physical characteristics? Advantageously, a system according to the invention will be compatible with a direct injection system for liquid phytosanitary products. For this purpose, it proposes a device for dosing phytosanitary products in solid form, comprising: • a tank of phytosanitary product in solid form • means for dosing the phytosanitary product in the tank, characterized in that it further comprises a mixing device comprising a stirring tank an injection pipe in which are introduced on the one hand the water and on the other hand the metered product, - an outlet made in the lower part of the tank and connected to a spray pump of the mixture produced. In its preferred embodiment, the mixer receives in its upper part an injection pipe in which the water and the powder will be introduced, in its lower part a suction pipe of the mixture and a return pipe allowing the circulation and therefore the stirring of the mixture formed. A conduit parallel to the injection duct of the upper part of the mixer joins the top of it at the bottom of the mixer. In this duct are installed sensors indicating the fluid height of the mixer. They are advantageously connected to means for controlling the amount of water introduced into the mixer, a water transport tank, a pump called a booster pump and a control valve. At the end of the suction pipe is a second pump called spray pump. In a preferred embodiment, a 3-way control valve is advantageously placed at the same time between the outlet of this pump, the return pipe to the mixer and the outlet to the spray bars. In its preferred form, a pipe provided with a non-return valve connects a water transport tank to the booster pump. At the outlet of this pump a 3-way control valve sends the desired flow of water into the upper part of the injection duct above the mixer. An injector at the inlet of the conduit causes the introduced water to flow along the wall of the conduit.

  Above the pipe is placed in turn, a cyclone that traps the metered product carried by a stream of air from the product tank, and a turbine creating this airflow. The tank for transporting solid products according to the invention has, for example, on the one hand an inlet intended to allow its loading and associated with a lid allowing a sealed closure of the inlet and, on the other hand, an outlet for supplying phytosanitary products. the volumetric doser. A preferred embodiment provides that the volumetric doser is in the form of a rotating part about an axis in the manner of a cylinder, the spherical surface of the rotating part has regularly distributed cavities, each cavity having an identical predetermined volume for each cavity, and that the dispenser is mounted in a sealed manner at the outlet of the tank so that the dispenser rotating about its axis the cavities are filled one after the other with the product being in the tank. In its preferred form, the rotation of the barrel is alternative with rotational stops in the filling axis of the cavities. To promote the production of a homogeneous slurry of uniform concentration, the metering device advantageously comprises a smoothing device downstream of the volumetric metering device, this device being intended to distribute over time the distribution of doses of phytosanitary product delivered by the metering device. volumetric. This smoothing device comprises for example a butterfly disposed in a pipe. The butterfly acts on the open section of the pipe and then acts in the manner of an hourglass when the open section is adapted to the metered product. A metering device according to the invention preferably also comprises control and management means acting in particular on the volumetric metering device so as to adapt the quantity of product dosed per unit of time as a function, in particular, of the desired product concentration in the mixer. . A preferred embodiment provides for a fan to create a closed-circuit air flow which carries the crop protection product of the volumetric doser into a cyclone which dissociates the air from the transported product and introduces it into the center of the injection conduit. Details and advantages of the present invention will become more apparent from the description which follows, given with reference to the appended diagrammatic drawing, in which: FIG. 1 is a schematic representation of a dosage device for phytosanitary products in solid form according to the invention; . The device according to the invention makes it possible in an original way to dose and inject phytosanitary products in the form of powder or granules into a spraying device of the type used in agriculture. This metering device may for example be associated with a direct injection device for spraying liquid products, as described for example in the document EP-1 184 085.

  The metering device according to the invention comprises first of all a tank 16 intended to receive a phytosanitary product in the form of powder or granules. It also comprises a volumetric dosing device and means for introducing the metered product into the injection pipe 17. The tank 16 is for example a tank made of synthetic material. It has in its upper part a large opening 31 for the introduction of phytosanitary products inside thereof. A lid 25 closes the opening 31 when using the metering device. On this cover 25 is fixed a product decompressing motor 26. This motor 26 fits during closing of a cover 25 on a decompacting shaft 27. This is for example a blade or a whip moved by the motor 26. On the opposite side to the opening 31, in the lower part of the tank 16, the latter has a hopper shape which guides the phytosanitary product contained in the tank 16 to an outlet 28. A inside the tank 16 is a gate 29 for deaerating the product contained in the tank 16 when it is moving towards the outlet 28. The outlet 28 of the tank 16 is equipped with a valve 32 for isolating the tank 16 of the dispenser 15. This is for example a drawer with a hole, drawer allowing the product of the tank 16 to flow into a position and closing the flow orifice of the tank 16 in the other position. The volumetric dosing device 15 is sealingly mounted at the outlet 28 of the tank 16. In its embodiment proposed here and shown in FIG. 1 in enlargement in a bubble, this metering device is in the form of a spherical member 151 rotatably mounted about an axis 157 and driven by a controlled motor 152. At the periphery of the spherical part 151, all5 around its equator, are regularly distributed cavities 153. All these cavities are of shape and shape. identical volume. The piece 151 is mounted so that the cavities 153 pass one after the other in front of the outlet 28 of the tank 16 when it rotates about its axis 157. A discontinuous movement is given by the motor 152 which stops every cavity in front of the outlet 28 the time of complete filling thereof and the need for dosing to maintain a desired product concentration in the mixer 23, concentration controlled for example by the flow meter 7 indicating the amount of water entering the mixer 23 In an embodiment proposed here a piece 156 held in contact on the sphere 151 by a set of springs not shown here, seals between the outlet 28 and the spherical part 151. The outlet 28 consists of a piece connecting link 155 which fits into the piece 156. At the other end of the latter, in contact with the sphere 151, is fixed a sealing member 154 also serving as a squeegee. Thus when the spherical piece 151 rotates about its axis 157 and the tank is filled with product in powder or granular form, the cavities 153 are filled one after the other and are leveled by 154 to obtain a precise volume constant. When the sphere 151 rotates the cavity 153 filled by gravity discharges its contents in a smoothing system 158. This is for example a throttle mounted in a pipe which is preferably substantially vertical. The position of the butterfly in the pipe can be adapted to the shape (powder or size of the granules) of the metered product. The butterfly then acts as an hourglass with variable and self-adaptive opening. Each dose of product poured into the smoothing system 158 then flows progressively in time between two rotations of 151. Control means (sensor, motors) not shown here allow the adjustment of this flow by the position more or less vertical throttle so as to obtain a continuous flow of product output of the smoothing system. Other smoothing means (vibrating plate for example) can also be envisaged. The product flowing out of the smoothing system 158 may flow by gravity into an injection pipe 17 or may be conveyed therein for example by a flow of air created by a turbine 19. A pipe 20 under the volumetric metering device 15 brings the product into a stream of air in a cyclone 18 which dissociates the product from the air and allows the product to flow in the center of the injection duct 17. The air stream is advantageously recycled as input of the volumetric feeder 15 through the pipe 21 and thus also serves for permanent cleaning cavities 153 empty. In the upper part of the injection duct 17 enters the pipe 30 carrying the water to be mixed with the phytosanitary products dosed. In an embodiment proposed here this water stored in a transport tank 1, is sucked by a booster pump 3 through a pipe 2 and a non-return valve 25. A variant not shown here consists in replacing the pump with a gravitational system that is to say, to position the tank 1 above the injection pipe 17 and to use gravity to bring water into the latter. Downstream of the booster pump 3, a control valve 4 divides the pump output flow in two: a part of the flow returns to the pump inlet, the other part of the flow rate is sent into the injection pipe 17 by the In the closed position, this regulating valve 4 completely interrupts the flow in the pipe 30, in the intermediate position this valve makes it possible to control the quantity of water introduced into the injection pipe 17 both at the height of the liquid. contained in the mixer and the amount of water leaving the ramps 22. The pipe 30 enters the injection pipe 17 by an injector 6 directing the flow of water so that it flows by rotating the along the wall of the duct 17 and thus creates a well in the center of which drops the crop protection products introduced by the cyclone 18. The lower part of the injection duct 17 enters the top of the mixer 23. A second measuring duct 8 placed parallel to the injection conduit 17 connects the top thereof to the bottom of the mixer 23. Preferably sensors 9 placed in this tube detects the height of liquid in the mixer. It is then possible through these sensors and acting on the control valve 4 to maintain a constant liquid height in the mixer. The spraying pump 11 draws the water product phytosanitary mixture through the conduit 10 and sends it downstream in a control valve 12 which divides the outflow of the pump in two. Part of the flow is sent to the spray boom 22. the other part of the flow returns via the pipe 13 in the bottom 5 of the mixer 23. This return creates a permanent circulation in the mixer and thus ensures the homogenization of its contents . In a preferred embodiment, the mixer has a calculated volume (for example between 10 and 20 dm3) and is used to promote mixing and dissolution of the phytosanitary product in solid form in water, its homogenization and finally degassing that engenders the incorporation of solid products in water. A metering device according to the invention preferably also comprises means for controlling and managing the flow rates, for example with a flowmeter 14 placed on the ramp output pipe 22, and a flowmeter 7 placed on the injection pipe 30. of water. It is then possible by acting on the control valve 4 to balance the input and output flow rates of the metering device.

  An example of operation of the device described above is indicated in the following text. The spraying pump 11 is for example the already existing pump of a spraying device. When this pump is running, it sucks up the liquid contained in the mixer 23. In a known manner, a regulator 12 is used to regulate the flow of slurry (mixture of water and plant protection products initially in solid form) towards a spray bar. depending in particular on the speed of advance of the sprayer and the amount of desired mixture spread. All returns 13 of the regulator 12 arrive in the mixer 23 ensuring a stirring therein. The metering device according to the invention relates to this mixer and the means used to dose the phytosanitary products in solid form and associate them with water. When the control valve 12 opens, a flow is established at the ramps 22, the mixer 23 is empty. The level sensors 9 placed on the mixer then indicate to the computer 24 to open the control valve 4 in order to send water into the mixer and restore the level. This level balancing function is made possible by a booster pump 3 which draws water from the tank 1 and delivers through the regulator 5 4 a part of the flow to the mixer 23 the other part returning upstream of the pump or directly in the tank 1. As an alternative embodiment (not shown in the drawing) and for low flow rates, the booster pump 3 can be removed and the tank 1 placed above the mixer 23 so that the water flows by gravity in the pipe 30 when the control valve 4 is opened. In stationary mode, the computer 24 will regulate the flow entering and leaving the mixer according to the information given by the flowmeters 14 located on the ramps 22 and the flowmeter 7 being the water inlet conduit 30 in the mixer. The products, especially phytosanitary products, are placed in the tank 16 which is then closed using its cover 25. A motor 26 is integrated in the cover 25 and engages on the unloading axis 27 when closing lid. In this tank 16, the grid 29 makes it possible to stop the lumps which are in the product to be injected. The decompacting device 27 makes it possible to aerate the product. A valve 32 for example of the sliding door type isolates the tank 16 of the metering system 15 located in the tank. When the valve 32 is open, the phytosanitary product falls by gravity into the cavities 153 calibrated and evenly distributed around the periphery of the spherical part 151 of the volumetric dosing device. Depending on the flow rate of water entering the mixer and given by the flowmeter 7, and the concentration of phytosanitary product desired, the computer 24 determines the speed of rotation of the spherical part 151 and therefore the flow of phytosanitary product leaving the tank 16. One of the characteristics of the metering device according to the invention is that this rotational movement is not continuous, each cavity stopping at least the time of its total filling in front of the outlet 28 of the tank 16. Sensors (not shown here) make sure this filling and reliability and the dosage. At each rotation of the spherical piece 151, the cavity is leveled by the piece 154 also serving to establish the seal between the product outlet 28 and the dispenser 15. The time between two doses of up to several seconds, it is necessary to have a smoothing system that returns the output of the dispenser to a continuous flow. This function is performed by the smoothing system 158 which acts as an hourglass. A flow detector (not shown) 5 is advantageously provided at this leveling system 158. The information collected by this detector is then transmitted to the computer 24. This detector can use for example photodiodes or shock sensors. or capacitive. If the smoothing system 158 uses a throttle (or any other means to control the passage section of the metered product), the computer 24 can control the opening (or closing) of the throttle according to the information received from the detector. flow. In order to accurately dose, it is necessary to calibrate for each phytosanitary product, the capacity of the cavities 153. A calibration procedure can be provided in the software managing the computer 24. Just at the outlet of the volumetric doser 15, a container can be introduced to recover the product leaving the cavities. The spherical portion 151 then performs a predetermined number of turns. The quantity of product collected in the container is then weighed accurately and entered into the computer 24. It then knows for the phytosanitary product dosed the weight and volume of each cavity. At the outlet of the volumetric feeder 15 the pipe 20 carries the product in a stream of air created by a turbine 19 to a cyclone 18 which dissociates the product from the air. The product then falls in the center of the injection conduit 17 located on the upper part of the mixer. The water injected by the pump 3 and the action of the injector 6, flows swirling along the walls of the conduit 17 creating a well in the center of which falls the powder. The powder water mixture is then stirred in the mixer 23 by the circuit: pipe 10, pump 11 and return 13. The air circuit is recycled through the pipe 21 at the inlet 33 of the metering device 15. This inlet is located on the lateral side of the metering device 15, facing the empty cavities 153 which go up after having emptied in the base part. Thus the recycling 21 has a double action: the purification of the air and the cleaning of the empty cavities. A variant of the system (not shown here) consists in replacing the cleaning action of empty cavities 153 by a jet of compressed air coming from a source other than turbine 19. Another variant of the system (not shown here) consists of to place the tank 16 and the metering system 15 above the injection line 17, the metered powder then simply falls by gravity in the center of 17, then it is freed from the air transport system. of the system (not shown here) is to mount in parallel several tanks identical to 16 with each volumetric doser identical to the 15 in order to dose several plant protection products simultaneously. The products are then transported by the single pipe 20 which connects the bottom of each volumetric doser.

  The device described above has the advantage of being able to adapt to phytosanitary products of very different shapes and physical characteristics. This device adapts to the constraints of agricultural spraying which requires a very wide range of concentrations of phytosanitary products and variations of ramp flow very important. It is possible, for example, with the same metering device simply by modifying the capacity of cavities 153, to carry out spraying with phytosanitary product concentrations of 20 g per hectare up to a concentration of 15 kg per hectare for ramp flow rates. fluctuating between 0 and 20 liters per minute. The device according to the invention can accept injectables requiring very variable mixing times. The described metering device also makes it possible to obtain a homogeneous slurry at the exit of the ramp and to guarantee a uniform concentration during the spraying. It is also suitable for being on board an agricultural tractor where it will be subjected to many vibrations and blows. The booster pump 3 makes it possible to put the water tanks 1 as low as possible on the tractors and thus to lower the center of gravity of the latter. The system for transferring the products dosed by air flow offers a the great advantage is the power to position anywhere on the tractor the tanks of products and especially at man's height in order to easily load them into product and secondly to dissociate the storage and dosing of the products of their injection into water which greatly increases the reliability of the system. The present invention is not limited to the preferred embodiment described above and the variants mentioned. It also relates to all variations of embodiment within the scope of the skilled person within the scope of the claims below.

In conclusion, here are some elements of my invention: The returns (13) of the pump (11) create a permanent circulation in the mixer (23) in order to stir and homogenize the mixture contained in the mixer (23) . The tank (16) has on the one hand an inlet (31) intended to allow its loading and associated with a cover (25) containing a motor (26) fitting into the unloading shaft (27) traversing vertically the tank (16), and on the other hand an outlet (28) provided with a valve (32) for supplying the phytosanitary product to the volumetric doser (15) as well as making the transport tank (16) removable and interchangeable. phytosanitary products in solid form. The volumetric doser (15) is in the form of a piece (151) rotatably mounted about an axis (157) in the manner of a barrel, in that the peripheral surface of the rotating part (151) comprises cavities (153) regularly distributed, each cavity (153) having a predetermined identical volume, and in that the dispenser is sealingly mounted (154,156) at the outlet (28) of the vessel (16) so that when the motor (152) rotates the barrel about its axis (157), the cavities (153) stop in the axis of the outlet 28, fill completely with the product and that the next barrel rotation control takes place when the need for product is necessary to maintain a desired product concentration in the mixer 23. The sealing member 154 also serves to level the cavity 153 when the part 151 rotates and thus to obtain a constant precise volume. additionally contains' d the control and management means (24) acting firstly on the volumetric dispenser (15) so as to maintain a desired product concentration in the mixer 23 as a function of the quantity of water entering and injected therein by the pump, 3 and on the other hand to control this amount of water injected into the mixer at a quaquity of liquid exiting the ramp 22 and thus maintain a constant volume in Ire mixer. 10 15 20 25 30

Claims (13)

  1. Device for dosing phytosanitary products in solid form, comprising: • a tank of phytosanitary product in solid form • means for dosing the phytosanitary product in the tank, characterized in that it comprises in addition, a mixing device comprising a stirring tank (23), an injection pipe (17) into which the water is introduced on the one hand and the metered product on the other hand an outlet made in the lower part of the tank (23). ) and connected to a spray pump of the mixture produced.   2. Dosing device according to claim 1, characterized in that a booster pump (3) sucks water from a tank (1) and injects a desired amount of water into the injection pipe (17). ) by a pipe (30) and by controlling a control valve (4).   3. Dosing device according to claim 2, characterized in that at the end of the pipe (30), an injector (6) flows by swirling the water along the walls of the injection duct (17).   4. Dosing device according to claim 1 to 3, characterized in that a pipe (20) under the metering means (15) brings the product into a stream of air in a cyclone (18) which dissociates the product from the air and let the product flow in the center of the injection duct (17).   5. Dosing device according to claim 1 to 4, characterized in that a pipe (8), parallel to the injection pipe (17) and connected from the top of the latter to the bottom of the mixer (17), contains sensors level (9).   6. Dosing device according to claim 1 to 5, characterized in that returns (13) of the pump (11) creates a permanent circulation in the mixer (23) in order to stir and homogenize the mixture contained in the mixer (23). ).   7. Dosing device according to claim 1 to 6, characterized in that the tank (16) has on the one hand an inlet (31) intended to allow its loading and associated with a lid (25) containing a motel r (26) fitting into the unthreading shaft (27) passing vertically into the tank (16), and on the other hand an outlet (28) provided with a valve (32) for feeding in phytosanitary product the volumetric doser (15) and to make removable and interchangeable tank (16) for transporting phytosanitary products in solid form.   8. Dosing device according to claim 7, characterized in that the volumetric doser (15) is in the form of a piece (151) rotatably mounted about an axis (157) in the manner of a barrel in that the circumferential surface of the rotating part (151) has cavities (153) regularly distributed, each cavity (153) having a predetermined identical volume, and in that the dispenser is sealingly mounted (154, 156) to the outlet (28) of the tank (16) so that when the motor (152) rotates the barrel about its axis (157), the cavities (153) stop in the axis of the outlet 28, fill completely with the product and that the next rotation control of the barrel occurs when the need for product is necessary to maintain a desired product concentration in the mixer 23.   9. Dosing device according to claim 8, characterized in that the sealing member 154 also serves to shave the cavity 153 when the part 151 rotates and thus to obtain a constant precise volume.   10. Dosing device according to claim 1 to 9, characterized in that it further comprises a smoothing device (158) downstream of the sphere (151), this device being intended to distribute the dose distribution over time phytosanitary product delivered by the discontinuous rotation of the sphere (151)   11. Dosing device according to claim 10, characterized in that the smoothing device (1.58) comprises a butterfly disposed in a pipe.   12. Dosing device according to claim 1 to 13, characterized in that it further comprises control and management means (24) acting on the one hand on the volumetric metering device (15) so as to maintain a concentration of desired product in the mixer 23 according to the amount of water entering and injected by the pump 3 and secondly to slave this amount of water injected into the mixer a quantity of liquid exiting the ramp 22 and thus to maintain a constant volume in the mixer.   13. Dosing device according to claim 1 to 12, characterized in that the computer (24) controls the control valve (4) from the information given by the flowmeter (7) placed on the water injection pipe (30), the flowmeter (14) placed on the ramp output (22) and the height sensors (9) to obtain a constant level in the mixer (23).