FR3029391A1 - AIR CLEANING METHOD AND DEVICE COMPRISING AT LEAST ONE NOZZLE - Google Patents

Abstract

The object of the invention is a method of stripping, in particular of vine leaves, by emission of a flow of air under pressure, comprising the following steps: Emitting at least two streams F1, F2 of pressurized air secantly, so as to generate an impact zone at the point of intersection and in the immediately upstream and downstream zone, emit these at least two intersecting fluxes to the leaves, adjust the impact zone of the at least two flows, so that the foliage to be removed is in the impact zone at the point of intersection I and in the immediately upstream and downstream PE zone. The invention covers the associated device.

Description

FIELD OF THE INVENTION The present invention relates to an air jet stripping method comprising at least one nozzle. The invention also covers the associated device. The technical field of the invention relates to the stripping of plants including vine plants. The vine is chosen as an example because it is directly concerned, it is the object of all the attention before the vintage, it is the standard image of the contradiction between the resistance of its vine and the fragility related to its fruits. Once the grapes are formed or berries, it is necessary to obtain the good maturity of the grain. However, simultaneously with the development of clusters, vegetation has also developed significantly. Excess vegetation was cut with gear, usually called pre-cutters. Nevertheless, these pre-cutters remain quite far from the median plane of the vine so as not to degrade the grapes.

We know that the clusters are carried by the vines in the lower part, regardless of the height of the vine and therefore regardless of the type of vine cultivation. The interest would be to be able to strip the right clusters, which is very delicate since it should not bruise the berries. Thus, the leaves shading said berries being removed, the sun is able to ripen the berries. Solutions have been made in the past to act effectively on the leaves and ensure a quality leafless without damaging the berries. Thus, the French patent FR 2 862 483 describes an air jet stripper which comprises at least two rotors with each at least one arm, the circles of these rotors being juxtaposed or secant. The arms thus have joint actions on the leaves so that this double action causes the tearing of the concerned leaves in a delicate manner that is to say with a low pressure, not likely to degrade the berries. It should be possible to further improve the efficiency of tearing the sheet, without significantly increasing the pressure which would adversely affect the quality of the stripping and especially what could damage the berries. In addition, the device must remain simple without multiplying the active or mobile organs so as not to burden the cost of the device and not to increase maintenance. It should be noted that there are already many owners of air strippers, on very many areas planted, including wine. The improvement of quality-4Ie the stripping must be studied in order to allow the sale of new equipment operating according to the method of the present invention with the stripping device according to the present invention but also to allow a "retrofit" of equipment already existing. The invention is now described in detail according to one embodiment, with reference to the accompanying drawings, drawings in which the various figures represent FIG. 1: a view of an arm with a stripping device including a single port nozzle. 2: a view of the effects of a two-flow nozzle; FIG. 3: a view of the effects of a three-flow nozzle. FIG. 4: a view of an arm of a stripping device equipped with a multi-orifice nozzle according to the invention. FIG. 1 shows an arm 10 with a single-port nozzle 12 mounted on a chassis 14 intended to support the arm 10 equipped with its nozzle 12, said chassis being secured to a displacement means such as a straddle tractor, not shown, in a direction F. The rotation of the arm 10 about its axis of rotation makes describe at the nozzle 12 a circle C and as the frame 14 is secured to the moving means in the direction E, the nozzle 12 describes a path along a line consisting of concatenated circles and offset.

The vine leaves, to mention only the exemplifying exemplary application, are therefore subjected to powerful air flows, strongly agitating the leaves which have a large leaf area, causing their tearing at the foot of the peduncle. The peduncle is subject to strong traction in different directions. The movements of the sheet are random and varied due to the displacement of the direction of action of the air flow. Indeed, even before the sheet has been able to return to a stable position, 5 suspended on its peduncle, after having been subjected to the action of a flow of air under one direction, it is once again subject to an action of a flow of air emitted in another direction. Any breakthrough is quickly transformed into complete breakage. As for berry clusters, they are not affected because they are less sensitive because they are farther away from the flow on the one hand and much heavier with respect to their surfaces on the other hand. Improvements have been made to the air stripping apparatus, in the form of a housing in which the arms move in order to emit a flow of air above the level of the bunches. The number of nozzles has also been multiplied with different lengths to cover larger areas.

The problem remains to make the action more effective with an improved leaf impact, from an identical arrangement. Indeed, the method of stripping according to the invention consists in emitting at least two intersecting fluxes so as to generate an impact zone at the point of intersection and immediately upstream and downstream of this point of intersection. , to emit these secant flows to the leaves and to adjust the position of the impact zone so that the area of the foliage to be eliminated is in the impact zone, at the point of intersection and in the immediately upstream zone and downstream. The method also includes moving the streams along a curve, which flow can be most simply a circle. The method provides for the emission of at least two streams, each following at least one direction, these directions being parallel. The method provides for the emission of at least two flows, each in a direction, these directions being intersecting. The method consists of emitting three symmetrical streams. The method operates in the manner now described with reference to FIG. 2 which shows a two-flow arrangement.

Thus, when the stream F1 is emitted, this stream forms a cone and when the stream F2 is emitted, this stream F2 forms another cone. These two streams have transmission centers C1 and C2 separated by a distance d. These centers C1 and C2 emission correspond to the tip of the respective cones.

These two cones have an intersection zone I, which occurs at the intersection of said two cones. At the right of this zone of intersection of the flows, a little upstream and downstream, the density of the air increases and generates an increased power of surface action since the speed is conserved and that the initial flow is generally laminar.

The method provides that the intersection of the at least two streams, hence the increase in density, is substantially in the middle position of the area to be stripped PE. The adjustment of the position of the intersection I of the two flows is obtained by approximation / separation of the two centers C1 and C2 of emission of the streams, therefore by a variation of d.

According to an alternative embodiment, the adjustment of the position of the intersection of the two streams is obtained by respective inclination of the directions of emission of the streams from the two centers C1 and C2 of emission of the streams The impact of the double flux is increased and the vine leaf is all the more effectively detached.

A compromise between complexity, cost, efficiency and the best embodiment according to the present invention is a 3-stream emission. In this case, at the intersection of the three streams F1, F2 and F3 is formed a rosette with three branches, symmetrical, which further enhances the impact in the central part. When the multiple flows fuse, immediately after the impact and downstream of the stripper zone, the laminar flow of the flow becomes turbulent, leading to a disorderly and very turbulent flow melting. The speed of the assembly is simultaneously reduced considerably, the impact on the berries becomes negligible. This is reinforced by the fact that the flows are emitted by a nozzle itself in rotation, so the flows are turbulent and swirling due to the rotation of the arm.

The impact is all the more effective because it is denser in the center, in spiral rotation in the center and swirling peripherally.

Thus, the method which provides for a division of the initial flux into at least two flows shows that, for an equivalent orifice area, the multi-flow is of greater efficiency than a single flow of the same section delivering the same flow, with the same pressure. Due to the existence of multi-ports for generating a multi-flow, it is necessary to have a greatly improved effect, to increase the pressure to compensate for the pressure drops. Indeed, the perimeter of two orifices with a unit area S / 2 being greater than the perimeter of a single surface orifice S, additional pressure losses occur. These pressure drops remain very small and the improvement effect is obtained even if the pressure does not compensate for this loss of load. Nevertheless, the pressure drop compensation makes it possible to maintain the speed of the flow that would have had a single flow of the same flow rate. Indeed, it is necessary to have a flow having a speed of impact sufficient to defoliate. FIG. 4 shows a device with a nozzle 120, equipped with at least two orifices, in this case 3 orifices 122-1, 122-2 and 122-3, which are symmetrical. These orifices are separated by a distance d. This nozzle is designed to be mounted on a rotating support arm. This device allows the implementation of the method according to the preferred embodiment of the present invention.

Claims (6)

REVENDICATIONS1. A process for stripping, in particular vine leaves, by emitting a stream of air under pressure, comprising the following steps: emitting at least two pressurized air streams in a secant manner, so as to generate a zone of impact at the point of intersection and in the immediate upstream and downstream zone, Emit these at least two intersecting flows to the leaves, Adjust the impact zone of the at least two streams, so that the foliage to be removed is in the d impact at the point of intersection and immediately upstream and downstream. 2. Process for stripping, in particular vine leaves, by emission of a stream of air under pressure, according to claim 1, characterized in that the emission of each of the at least two streams is carried out in one direction, these directions being parallel. 3. Process for stripping, in particular vine leaves, by emission of a pressurized air stream, according to claim 1, characterized in that the emission of each of the at least two streams is effected in one direction, these directions being secant. 4. A process for stripping, in particular vine leaves, by emission of a stream of air under pressure, according to any one of the preceding claims, characterized in that the method consists of emitting three symmetrical streams. 5. A process for stripping, in particular vine leaves, by emission of a flow of air under pressure, according to any one of the preceding claims, characterized in that the flows are displaced along a curve. 6. stripping device for carrying out the method according to one of claims 1 to 5, characterized in that it comprises a nozzle (120) provided with at least two orifices (122-1, 122-2 and 122). -3), separated by a distance d.