WO2008053116A2

WO2008053116A2 - Insect protection screen

Info

Publication number: WO2008053116A2
Application number: PCT/FR2007/052263
Authority: WO
Inventors: Jean-Paul Ducol; Jacques Tankere; Thierry Boulard; Jacques Fargues; Jean-Claude Roy
Original assignee: Mdb Texinov Sa; Institut National De La Recherche Agronomique
Priority date: 2006-10-31
Filing date: 2007-10-29
Publication date: 2008-05-08
Also published as: FR2907805B1; EP2079341A2; FR2907805A1; ES2401302T3; IL197822A0; MX2009003110A; IL197822A; WO2008053116A3; EP2079341B1

Abstract

The anti-insect screen of the present invention comprises a net made of textile threads, said net being made by cast-off stitch knitting on a warp or Rachel machine.

Description

INSECT PROTECTION SCREEN

FIELD OF THE INVENTION

The invention relates to a screen more particularly intended to prohibit the passage of insects to protect crops, whether vegetable or horticultural, including greenhouse crops or even field crops.

PRIOR STATE OF THE ART

The intensive nature of crops has long been met with the ravages of insects, whether they be indigenous or from migrations arising from trade between continents. These insects attack some crops by developing diseases that partially or totally destroy them, affecting production yields or making products unfit for consumption.

In order to combat these ravages, it has long been proposed to use nets, closing openings in greenhouses or positioned above crops in the open field, thus to barrier against insects and prevent them from entering the areas of sensitive crops. The introduction of such nets eliminates chemical treatments whose use tends to greatly decrease under the ecological pressure of consumers, particularly in relation to the so-called "organic" products.

Thus, the nets available today are made by weaving using simple armor such as canvas or taffeta with a cross warp son and perpendicular weft. Such a net is for example described in WO03 / 074771.

Mesh nets having fairly large openings, typically of the order of 850 to 1,000 μm, or even smaller, of the order of 350 μm, are also known. However, the armor used in such nets define low rates of opening, typically of the order of 35 to 40%, providing certainly the mechanical barrier against insects, but on the other hand do not allow a good exchange of air and therefore opposing good aeration of crops. Indeed, because of the woven nature of the nets, we must use relatively large diameter son so that the resulting texture has a good behavior over time and thus avoid a risk of slippage of the son network, likely to change the size openings and therefore affect the mechanical barrier against insects.

In addition, because of the implementation of large diameter son, the resulting net has a certain rigidity, likely to oppose the folding and unfolding whose nets are likely to be subject because of their positioning, especially at the level of the moving parts of the opening of the greenhouses.

Finally, the implementation of woven faces the risk of fraying occurring during their cutting and implementation on the support structures on which they are arranged.

SUMMARY OF THE INVENTION

The object of the invention is to provide a screen, intended to oppose the ravages of insects, and implementing a net of a new type, freeing itself from these various disadvantages and in particular fulfilling the primary function that it is devolving, namely the realization of an insect barrier, while offering higher aeration rates to the nets of the prior art, and may also have a longer life.

According to the invention, this insect screen consists of a net based on textile yarns made by knitting with knitted stitches on machine chain or Rachel.

In doing so, this particular technique implementing the mesh of warp yarns, possibly with sectional or non-sectional wefts, gives greater cohesion to the resulting net. This technique therefore allows the implementation of very thin monofilaments, thus contributing to obtain a factor or opening rate greater than the nets of the prior art.

Thus, the surface of the orifices defined by the stitches relative to the surface occupied by the strands becomes significantly larger. The supply of air and light, both constituting factors determining growth of crops, is greatly improved. In addition, the technology knitting jetted mesh makes it possible to vary the geometry of the orifices, also to lead to the definition of orifices of very small dimensions, more particularly adapted to the fight against specific insects also very small.

According to the invention the opening ratio defined as being the ratio of the surface of the orifices on the total surface of the net is greater than 50%.

According to a first embodiment of the invention, the net defines orifices of substantially square or rectangular shape obtained by knitting stitches with implementation of sectional weft son.

According to a second embodiment of the invention, the thread defines orifices of substantially hexagonal shape, obtained by knitting, but the weft son are variable jetty and not constant.

Thanks to the invention, it is possible to obtain a net whose openings are smaller than 250 μm in at least one of the dimensions and between 250 and 1000 μm in the other direction.

According to an advantageous characteristic of the invention, it takes advantage of the knitted mesh knitting technology to define gripping areas at the net suitable for its handling, especially at the opening of the greenhouses.

BRIEF DESCRIPTION OF THE DRAWINGS

The manner in which the invention can be realized and the advantages which result therefrom will emerge more clearly from the following exemplary embodiments given as an indication and not by way of limitation in support of the appended figures.

Figure 1 is a schematic illustration of a net obtained by weaving in accordance with the prior art.

Figure 2 is a schematic representation of a net obtained according to a first embodiment of the invention, defining rectangular shaped openings.

Figures 3 is a view similar to Figure 2, wherein the holes are square. Figure 4 is a schematic representation of a net obtained according to a second embodiment of the invention, defining hexagonal shaped orifices.

Figures 5, 6, 7 and 8 illustrate the technology implemented according to the type and shape of the desired orifices.

Figures 9 and 10 illustrate the positioning of the net according to the invention respectively at a greenhouse and at the opening of a greenhouse. Figure 11 is a schematic representation illustrating the embodiment of the attachment system according to the invention.

MODES OF REALIASTION OF THE INVENTION

Figure 1 shows an insect net of the prior art obtained by weaving. We denote by 100 the son of chains, and by 101 the weft son.

It is observed that this weave defines orifices 102 of surface S1 of substantially rectangular shape.

In order to achieve a certain cohesion of the net resulting from the weaving operation, the warp and weft threads 100, 101 are of relatively large dimensions so as not to affect the size of the orifices 102 and in particular their surface S1. Indeed, in the case where the son 100, 101 are too thin, it is observed that the network has no mechanical strength, the son sliding between them, so that the size of the orifices 102 is no longer preserved, This can lead to bigger holes, which are unsuitable for the insect barrier function. As a corollary, because of the use of large diameter wires, these tend to reduce the passage of air, affecting the climatic conditions of the crops to be protected by such a net.

FIG. 2 shows a schematic representation of a first embodiment of the net according to the invention. This is achieved by the technique of jersey knitting discarded, such as for example implemented on trades type RACHEL marketed by the companies KARL MAYER or LIBA.

This net comprises, according to this embodiment of the chain 204 mesh with weft son 205, in this case of sectional nature, as will be described later in more detail. This knitting defines orifices 202 of surface S1 '. It is noted that the ratio of the surface S1 'with respect to the surface S2' defined in said figure and corresponding to the sum of the surface S1 'of the orifice 202 and that occupied by the wires defining the orifice in question. is much larger than the ratio of said surfaces resulting from the net obtained by the conventional weaving technique of FIG.

It is also possible to observe in this figure a double path of the fine wires in this case of frame 205, thus constituting a blocked network without risk of slippage and thus, making it possible to keep constant the dimensions of the orifices 202 thus defined. Because of the use of fine wires, and especially monofilaments, typically with a diameter of between 0.04 and 0.1 mm, it is possible to obtain a much higher factor or opening ratio than the product of the prior art. , promoting the passage of air through the net without affecting the function of insect barrier devolved to the net.

Measurements carried out in the laboratory in relation to the losses of charge and the passage of air through such nets at different speeds show that the difference in permeability of this type of net with respect to conventional weaves is very clearly improved since it leads to a coefficient of pressure drop (measured in the wind tunnel to analyze the passage of the wind at different speeds) less than 4 and even likely to reach values close to 1.6.

The following variations are reproduced in the table below for the observed variations in the coefficient of pressure drop, flow reduction and decrease of the opening flow rate with respect to different nets obtained in accordance with the invention with regard to control nets corresponding to a woven fabric. Figure 1.

N ° Net Coefficient of Coefficient of Decrease Decrease of the pressure loss flow rate% flow ouyrant%

I 1.74 0.76 41 27

II 2.14 0.68 45 31

III 2.52 0.63 48 34

IV 3.49 0.54 54 40

V 3.56 0.53 55 40

WITNESS 4.56 0.47 59 45 Sample I corresponds to a net whose openings have dimensions of 500 x 500 μm, more particularly adapted to the protection against various insects: aphids, flies, whiteflies ...;

Samples II and III correspond to a net whose openings have dimensions of 250 x 730 μm, more particularly adapted to protection against Bemisia Tabachi;

Samples IV and V correspond to a net, whose openings have dimensions of 290 x 320 μm, more particularly adapted to protection against thrips. The control net is a conventional woven with 0.20 / 0 threads, 22 mm and with a porosity (ratio between the surface of the holes and the surface unit) of the order of 38/40%.

The measurements are made in the wind tunnel; we note the speed of the wind, its modification after the passage through the net as well as various factors which then make it possible to determine by calculation, the decreases of flow on the net itself and in its position of use, ie when placed on a greenhouse structure. The flow rate reduction values indicated thus correspond to data directly usable by the builders and horticulturists to determine their crop operating conditions.

In addition, it is known that the passage of air through a net is not related proportionally to its opening rate, but is also correlated to the geometry of the orifices that constitute it. Indeed, the geometry of the orifices also influences the behavior of insects to prevent them from crossing the mechanical barrier constituted by the net.

The invention makes it possible to define different types of geometry of opening by the implementation of the technology "discarded mesh".

Thus, if the geometry of the openings of FIG. 2 is rectangular, that of FIG. 3 shows holes of substantially square shape, and that of FIG. 4 shows holes of hexagonal shape.

FIGS. 5 to 8 illustrate the technology making it possible to obtain these different geometrical shapes. Thus, the technologies illustrated in FIGS. 5 and 6 make it possible to obtain threads, the orifices of which are of rectangular or square shape, the binding being obtained according to the technology of the stitched mesh.

The reference Bl illustrates the chains which work on a single column of needles. The wire guide bar works in 00/22 armor.

Thread B2 Illustrates a sectional weave working by means of a wire guide bar according to the 10/01 weave, the assembly having been shown for a fine gauge of twenty-eight needles per inch (25.40 mm)

The distance e separating two adjacent chains corresponds to the space between two needles, the diameter of the wire being selected to determine the width of the orifices 202, 302 of the net. It is thus possible to obtain orifices of 500 × 500 μm. Such nets are advantageously used. the insect thrips, reducing the size of the side to 350 μm.

FIG. 6 is a view similar to FIG. 5 but implementing a larger gauge, typically 22 needles per inch, and with a different ratio between the warp density and the weft density, so as to obtain a thread whose orifices are rectangular in shape, typically 250 μm wide for a length of 730 microns.

These nets are particularly suitable for protection against insect pests that generally attack vegetable and horticultural crops. They then transmit diseases which, previously, could only be combated by chemical treatments. Except we know how much these techniques are more and more abandoned with the need for organic farming and / or more respectful of the environment

On the other hand, there are certain cases of specific insects that act more specifically on certain crops: for example "bemisia tabachi", Thrips or aphids ...

FIG. 7 represents another type of binding, making it possible to obtain a thread whose orifices have dimensions of 700 .mu.m to 900 .mu.m on the side with a wire of 0.08 to 0.10 mm, and which can serve as a barrier against insects like aphids and some flies or whiteflies. According to this technology, the chains B1 are of the type previously described but working in a 10/10 armor. On the other hand, the threads B2 consist of a gill yarn and alternatively embroidering. particularity of a very great holding and dimensional stability.

Finally, FIG. 8 makes it possible to obtain a thread, the orifices of which are of substantially hexagonal shape, making it possible to define a honeycomb structure. Such a net is advantageously used to prohibit the passage of particular insects, of the type mentioned above. This geometry has the advantage of not being directional and therefore of presenting a uniform isotropic behavior in all directions.

According to this particular embodiment, the warp threads B1 work on two needle columns in contrast to the three previous embodiments.

Typically, the working armor of the corresponding needles is 10/01/10/12/21/12.

The weft yarns are variable jetty and not constant as for FIG.

The net of the invention is likely to have both weathering and ultraviolet resistance characteristics to provide multi-year functionality. For this purpose, the constituent son is made of polyethylene or polypropylene, the base polymer receives an antioxidant.

However, one may wish to implement biodegradable nets to meet certain environmental type constraints for example. For this purpose, son of polyester, polyamide or polylactic acid for example.

FIGS. 9 and 10 show examples of mounting the net according to the invention. It can conventionally close one of the 906 or the two lateral faces of access to a greenhouse 907. It can also be in the form of a lateral strip 908 extending along the entire length of the greenhouse, as shown in Figure 9, and intended to close the greenhouse 907 at this level against insects, but not against the passage of air.

Moreover, some greenhouses are provided with openings 1009, including glass greenhouses, to allow to vary the climatic conditions that prevail in the volume they define, such openings being hinged 1010 on the greenhouse. It is also desired to protect insects despite the use of such an opening, so that it is matched with a net 1011 according to the invention for, although allowing the passage of air , prohibit access to insects (see Figure 10). The net in question is then secured by any means to the respective edges of the fixed part and the movable part of the opening.

On the other hand, and in order to allow the easy manipulation of this opening, systems 1012, 1013 for retracting the net towards the interior of the greenhouse are used when it is desired to close off the opening in question. To this end, traction is performed on said net by any means, and in particular a linkage system or a system of ropes secured to the inner face of the net, and more particularly to a reinforcing strip 1014, which can be reported by binding over the entire length of the net.

According to one characteristic of the invention, and for this purpose, there are reported on said inner face additional technical threads 1110 (FIG. 11), suitable for creating loops 1111 at which the return means or the rods 1112 are secured. These loops 1111 are defined by the introduction of mechanically resistant technical yarns always by knitting, these yarns being bonded into zones 1113 with a specific bonding strong enough to form a sufficient link with the net, without the risk of tearing. use.

These loops are made during the manufacture of the net, and are distributed relatively uniformly and periodically along the net, and for example spaced every 30 cm. Thus, the net can be unfolded or folded at will, during the movements of the opening, with ease of retraction inside the greenhouse.

These loops or attachment zones are constituted by son, or of the same nature as that of the son constituting the net, or of different nature, and in particular larger diameter and more mechanically resistant.

Other folding modes can be implemented as an "accordion" fold, a "bundle" fold and in these cases, the threads and buckles reported directly in the net during its manufacture, serve as an effective means of fastening by avoiding all the random and costly solutions of reinforcing or piercing add-on seams for fasteners. According to a feature of the invention (not shown), the net is likely to include reinforcing technical son, more particularly to improve the wind resistance.

These reinforcing son are thicker than the constituent son of the net itself, and having a specific resistance. They are separated from one another by a distance of between 1 cm and 20 cm depending on the importance of the desired reinforcement, said reinforcement son being reported directly on the net during the manufacture of the latter.

It is conceivable the whole interest of the screen according to the invention, which allows to fulfill its primary role of barrier against insects, while ensuring an opening rate more in harmony with the climatic conditions that want to create market gardeners or horticulturists in their greenhouses, or on field crops.

Claims

1. Insect screen consisting of a net based on textile threads characterized in that the net is made by knitting mesh knitted machine chain or Rachel.

2. Insect screen according to claim 1, characterized in that the constituent frames of the net are of sectional nature.

3. Insect screen according to one of claims 1 and 2, characterized in that the constituent son of the net are constituted by monofil.

4. Insect screen according to claim 3, characterized in that the diameter of the son is between 0.04 to 0.1 mm

5. Insect screen according to one of claims 1 to 4, characterized in that the opening rate of the net, defined as the ratio of the surface Sl 'orifices (202, 302, 402) on the surface total net is greater than 50%.

6. Insect screen according to one of claims 1 to 5, characterized in that the coefficient of loss of load of the net is less than 3.

7. Insect screen according to one of claims 1 to 6, characterized in that the net defines orifices of substantially square or rectangular shape obtained by knitting stitches with implementation of sectional weft son.

8. Insect screen according to one of claims 1 to 6, characterized in that the thread defines orifices of substantially hexagonal shape, obtained by knitting, but whose weft son are variable jetty and not constant.

9. Insect screen according to one of the preceding claims characterized in that the net has openings less than 250 microns in at least one of the dimensions, and between 250 and 1000 microns in the other direction.

10. Insect screen according to one of claims 1 to 9, characterized in that the constituent son of the net are made of polyethylene or polypropylene, the base polymer optionally receives an antioxidant.

11. Insect screen according to one of claims 1 to 9, characterized in that the constituent son of the net are made of polyester, polyamide or polylactic acid.

12. Insect screen according to one of claims 1 to 11, characterized in that defined on one of the faces of the net of the attachment zones of a return means, obtained directly by knitting at the realization of the net itself.

13. Insect screen according to claim 12, characterized in that the attachment zones are constituted by son, or of the same nature as that of the son constituting the net, or of different nature, and in particular of larger diameter and more mechanically resistant.

14. Insect screen according to one of claims 1 to 13, characterized in that the thread comprises reinforcing technical son, thicker than the constituent son of the net itself, and having a specific resistance, said technical son being separated from each other by a distance between 1 cm and 20 cm depending on the importance of the desired reinforcement, said reinforcing son being reported directly on the net during the manufacture of the latter.