BR202018069938U2 - biodegradable packaging for packaging, hatching and distribution of wasp eggs as a complement to the biological control of agricultural crops and gardens - Google Patents

Abstract

Biodegradable packaging intended for packaging, hatching and distribution of wasp eggs as a complement to the biological control of agricultural crops and gardens, consists of a spherical, prismatic, or differently shaped capsule, made up of biodegradable charac- teristics, obtained of cellulosic material rigid from the breakdown of fibers from the cellulosic raw material used, which is subjected to compaction in a mold, later drying, and assembly of the final product, effectively biodegradable, and therefore suitable for dispersion in crops or gardens, as alternative to biological pest control, which comprises an agronomic technique that uses natural enemies to control insect pests in plantations, thus promoting sustainable agriculture to combat the indiscriminate use of pesticides, which cause damage to the environment and health human. present invention fits the international classification of patents in its section a - human needs / agriculture, subsection ao1m - imprisonment, capture or chasing away animals; apparatus for destroying harmful plants or animals, subsection at 1 m 29/28 - chasing apparatus specially adapted for insects.

Description

BIODEGRADABLE PACKAGING PACKAGING, ECLOSION AND DISTRIBUTION OF MICROWAVES AS A COMPLEMENT TO THE

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FIELD OF APPLICATION (001) The present innovation applies to the agronomic sector of application in the sector of biological pragash control technology. The objective was to develop a biodegradable capsule 'suitable for dispersion in crops or gardens, in order to allow hatching and wasp release as a complement to other biological pest control technologies. ’[

I (002) One of the main problems of sustainable agriculture concerns the use of pesticides in the control of weeds, pests and diseases. From the global modernization of agriculture, the large-scale use of t ¹ pesticides has increased as the need to obtain greater productivity (CAMPANHOLA & BETTIOL, 2003).

(003) However, the increase in the use of chemicals in the control of unwanted organisms, in addition to being harmful to human health and the environment, brought other problems, such as, for example, the appearance of pests and weeds resistant to these products (CARNEIRO et al. 2012), which is why efficient and less toxic alternatives are being studied to replace pesticides.

(004) Among the alternative methods of pest and disease control, biological control is characterized by being one of the most efficient, since it provides a good result and does not harm the environment (PRATISSOLI et al., 2005). An example of biological control is the use of the parasitoid Trichogramma spp. (Hymenoptera: Trichogrammatidae) in the control of

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caterpillars in tomato, soy, sugar cane, cotton plantations, among other crops (PARRA & ZUCCHI 2004). ¹ | l ¹ .1 »I if | (005) Parra & Zucchi (2004) claim that the successful use of Trichogramma spp. for biological control basicamèrite occurs due to the ease of mass creation of insects in the laboratory. The authors I 'also state that in Brazil, about 10 billion Trichogramma ί ¹ 1 spp wasps are produced and released in crops spread throughout the country per year.

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However, there is still a deficiency in the packaging and methodologies for releasing the insect in the field.

(006) Currently, biological control agents are produced artificially in the laboratory inside eggs of alternative hosts, and dispersion in the field can be done by releasing 'adult agents (wasps) created in the laboratory (case of control' of the borer).

Ί 'cane) just before hatching, or in pupal stage, or in the form of alternative host eggs, and field releases can be

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J carried out after the birth of the adult insects, or before, when the

1 'Eggs are impregnated in cardboard-type paper bags. For dispersion in this case, the wallets are cut into small pieces' and placed on the plant for subsequent hatching. <

: ‘I (007) For their dispersion in the field, these portfolios are cut and read manually placed on the plants (CRUZ, 2014; HAJ / et al., 1998). li '

Another way for the release of wasps in the pupa phase is the use of semi-spherical packaging and closed with a paper tape and / or paper adhesive card, which are released into the field manually or through a mechanical system according to the patent filed. by KOPPERT DO BRASIL HOLDING LTDA (2015).

(008) In some situations it is possible to release capsules containing parasitoid eggs by plane. These eggs will hatch and leave the

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capsule, preventing predation by other species (ZACHRISSON & PARRA, I ' ¹

1998). An example of one of the dispersion modes is the packaging created by KOPPERT DO BRASIL HOLDING LTDA (2015) ^ that uses biodegradable semi-spherical capsules, as shown in Figure 1, ¹ I ¹ ' ¹ ' in which the capsules for control are presented biological composition composed of live parasitoids of the genus Trichogramma galloi., is a stage of pupal development. [(009) In view of the above, the importance of 'finding alternative packaging that favors the release and action of insects against undesirable agricultural agents due to the deficiency in the .1 release processes of Trichogramma spp. to control agricultural pests in Brazil, as well as the need for further research aimed at efficient insect release methodologies.

(010) In this context, the present innovation consists of a biodegradable packaging complementary to biological control, using microvespas in the stage of eggs or pupa, for use in crops or gardens in order to carry out pest control, and therefore, to reduce, or eliminate, the need to apply insecticides. I

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I ¹ (011) This biodegradable packaging (capsule) is obtained from a cellulosic pulp originated from the breakdown of the fibers of the material | l | used raw material, which can be either paper, cardboard or virgin cellulosic mass, as well as those from recycling, as well as others

I biodegradable polymers, alone or mixed with native starch from any botanical source, for subsequent compaction of this cellulosic pulp in a semi-spherical mold, or in a different prismatic format, or in other formats and materials, resulting in a spherical final product, or prismatic, or in a different shape, resulting from the union of two halves of the capsules.

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H (012) iJ The packaging material, as mentioned above, was selected due to its potential to resist the conditions of 'application in

I 1 ,,,, field, which were imposed through tests of resistance to bending, tests of resistance to climatic conditions ibm field and

I ¹ 1 * t testing of capsule launches. All these tests foranh ¹ to certify and validate the application of biodegradable packaging for biological control.

PRODUCTION, USE AND COMPOSITION PROCESS ’l '(013) The present innovation is obtained by following the following steps:

(014) Step I - Preparation of the material;

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i. (015) Stage II - Disaggregation of raw material; I 'I (016) Stage III - Conformation and preparation of capsules;' (017) Stage IV - Supply with biological control agents;

I · (018) Step V - Assembly of the product;

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(019) Step VI - Method of use. | '| il ¹ '' (020) Stage I: It consists of preparing the material (raw material) for the production of cellulosic pulp, from cutting and shavings of cardboard or virgin cellulosic material, as well as those from recycling, in pieces squares of variable size, but preferably of 10 (ten) millimeters of edges, in order to facilitate its disaggregation in the disaggregating equipment, but without crushing the excess shavings, because in this case, the resulting final product loses much of its mechanical strength.

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cellulosic, (021) Stage II: It consists of the disaggregation of the raw material that is made with the addition of water, as a way to obtain the suspension of fibers in water, also called cellulosic pulp. Suspensions from 8 to ül 'b

3%, preferably 5% (five percent), weight of de · suspension of cellulose in water can be used for the product i: l developed. This method of disintegration ensures that the cellulose fibers do not break, and therefore, preserving the mechanical strength i of the final product, important to resist handling, folding, shocks and bad weather that normally occur in the field. !

(022) Stage III: It consists of the formation of cellulosic pulp in capsules. After be obtained pulp mass virgin or matéria'prima coming from recycling, the formation of the packaging (capsule) ¹ is made by depositing the pulp in the mold cavity projected onto ¹ l ^'11 semispherical shape, or form prismatic half, or of different formats. Once the cavity is filled, cold forming is carried out by pressing the material through a countermold. The formation of b | II packaging can also be done by a process similar to that used to manufacture egg cartons, using vacuum molds. | (023) After pressing, the compacted cellulosic pulp in the desired shape is detached from the mold and the capsule halves proceed to the drying process, which can be carried out in an oven or at ambient air in various temperature combinations, depending on the final moisture. Leftovers of material, or capsules with defects can be reused, stirred again in water. j (024) Step IV: It consists of placing a piece of paper or non-woven fabric (TNT), or any other material compatible with the use and that does not cause intoxication of the eggs or pupae, inside a half of the capsule,

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impregnated with host eggs (or pupae) parasitized by microvespas obtained in the laboratory.

i '(025) Step V: Consists of joining the two halves of the capsule through

Ί [a biodegradable glue generated from corn, wheat, cassava starch

I 'Ί as well as any other type of starch suitable for the production of biodegradable glue. Thus, the packages provided by pupae or parasite eggs will be ready to be dispersed in the field (crops as well as gardens).

I '' (026) Stage VI: Consists of the method of dispersion of the capsules for biological control, according to the model of Dobzhanski and Wright (1943) on the range of action of the microvespas, and according to Haji et al., 2002, which recommends approximately 5.4 million parasitoids per hectare for

I field distribution, with a spacing of 14 meters between each one. The distribution can be carried out using a motorcycle equipped with a pressurized air launch device, or if the device is not available, the distribution can be done manually, or using an unmanned aerial vehicle (drone), airplane or other distribution medium.

'.il (027) Due to the lack of standards and standardized tests for these

I 'I tests, a methodology was developed as presented below <in order to obtain the necessary results for the determination of the use or i

not the material and the final product (packaging). The quality »of the product is ensured through tests carried out with the selected raw material, or already on the final product. The material must withstand bending tests with at least 50 (fifty) repetitions, and resistance tests to climatic conditions in the field, such as exposure to rain, sun and humidity, for 10 (ten) days.

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Page 6 of 10 (028) Circular raw ® Rub samples were used for raw material testing. ·

flat (sheets) of 110 (one hundred and ten) millimeters in diameter] as specimens of the material from the cellulosic pulps of these raw materials I disaggregated in water with 8 to 3% (eight to three percent) of suspension weight through steel mesh pressing. For tests of the ‘I tl final product, model capsules were made with the aforementioned cellulosic material, according to the manufacturing process already presented for the biodegradable packaging for biological control.

(029) The evaluation of cohesion between the fibers that make up the cellulosic material was carried out in successive folds in opposite directions without the material breaking. The bending resistance test consisted of bending the material formed at an angle of 90 ° (ninety degrees) to one side, returning to angle 0 ^o (zero degree) and then bending 90 ° (ninety degrees) to the other side, being this process repeated until the

I start of the failure (tear). The material proved to be resistant and with excellent aggregation between its fibers, withstanding more than 50 repetitions of folding until the appearance of the first defibration. ‘• i 1 (030) A methodology was also established to assess the effect of climatic conditions, such as exposure to rain, sun 'and humidity, similar to those that the material may suffer if placed in the field. The method adopted was to fix three samples of the material, and also of the final product (capsule), on an open-air lawn, exposed to the sun and rain for 10 (ten) consecutive days, the time established according to the life cycle of the biological control agents used.

(031) During the test period, the monitoring of the performance of the samples, both of the material and of the capsules, was done by visual inspection of their physical aspects daily evaluated for their disintegration, deformation, tears, or all these consequences at the same time. For the record of rains it was installed at the test site

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a static rain gauge, as well as a thermometer to record the average daily local temperature. During the ten days, the averages of

I I daily temperatures registered a minimum of 14.5 ° C, and a maximum of 28.5 ° C, with rains of 45, 21 and 6 mm / cm. After the testing period ^ it was found that the product and material did not present bl., Disintegration or cracks, and did not undergo considerable.

5 ', i its structure. Thus, these results showed that the material withstands field storms as required.I (032) The way in which the product was used in the field was ^ evaluated by launching the capsules on the plantation, which can be done ^ for example, by a motorcycle equipped with a launching tube (propellant gun), equipment to distribute them. Launch tests were carried out in order to certify the product's resistance, both in relation to the launch pressure and in relation to the impact on the ground. The materials used in the test for the simulation of the capsule launching equipment was a 0.75 HP WEG LR 38324 compressor and a 1-inch inside diameter PVC pipe. This methodology made it possible to fire the capsules by pressurized air, and allowed to measure the distance, magnet that the launch reached, as well as visually verify if they resisted the launch and shock with the ground. ,

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(033) In evaluating the performance of the capsules in their lil release test, the results allowed to establish that in accordance with

I that were proposed, the capsules can resist the initial force of the launch and the impact on the ground at the end of the trajectory in a range of 2 to 10 meters. For these reasons, it is concluded that the product is able to withstand application as a packaging for packaging; hatching and> -Γ distribution of microvespas at the pupal stage in crops or gardens.

Claims (6)

CLAIMS? i I 1. BIODEGRADABLE PACKAGING INTENDED FOR ECLOSION ACTION, AND 'DISTRIBUTION OF EGGS OF VES COMPLEMENT TO BIOLOGICAL CONTROL i DE! , ¹ , ¹ ii AGRICULTURES AND GARDENS characterized by being 'biodegradable for biological control with set conception and use based on stages, which are ¹ ' (NAME ΝΤΟ,! \ S AS .'cultivated in the n method capsule: Stage I a; Stage III Preparation of the material; Step II - Disaggregation of the raw material Confirmation and preparation of the capsules; Step IV - Supply with biological control agents; Step V - Assembly of the product; Step LVI - Method of use. ' 2. BIODEGRADABLE PACKAGING INTENDED FOR PACKAGING, I < ECLOSION AND DISTRIBUTION OF WASP EGGS AS A COMPLEMENT TO THE BIOLOGICAL CONTROL OF ’CULTIVES AGRICOLAS AND GARDENS according to claim 1, Stage VI h Method of Use, characterized by the non-dispersion of the capsules in flooded regions due to the potential infiltration of water through the holes [outflow of the wasps, as well as the increase of interior humidity, ¹¹ Γ i impairing the functionality of the biological contraceptive agents stored in its interior. II '| 3. BIODEGRADABLE PACKAGING INTENDED FOR PACKAGING, 'ECLOSION AND DISTRIBUTION OF WASP EGGS AS COMPLEMENT TO THE BIOLOGICAL CONTROL OF J CULTIVES '' AGRICULTURAL AND GARDEN according to claim | 1, Step V Assembly of the Product, characterized by having a spherical or prismatic shape, of different shapes, the halves being joined by biodegradable glue from corn starch, and / or wheat, and / or cassava, as well as any other type of starch suitable for the production of biodegradable glue I. *; Page 1 of 2 h * I u j | i i p> Ν '

4. BIODEGRADABLE PACKAGING INTENDED FOR PACKAGING, ECLOSION AND DISTRIBUTION OF DRESSED EGGS AS A COMPLEMENT TO THE BIOLOGICAL CONTROL OF ίΙ CULTIVOS li, 'I'] AGRICULTURAL lE GARDEN according to claims 1 and 3, characterized in that the spherical or prismatic shape, various forpias preferably sendol prepared in hexagonal, d, ^j which permits | l ¹ (I complete utilization of waste material without facilitates the dispersion of packages in the field due to their aerodynamic shape, ^ using a compressed air device to launch the packages. 5. BIODEGRADABLE PACKAGING INTENDED FOR CONDITIONING, ECLOSION AND DISTRIBUTION OF EGGS EGGS AS A COMPLEMENT TO THE BIOLOGICAL CONTROL OF ¹ AGRICULTURAL AND GARDEN CROPS According to claims 1, 3 and 4, l ^1,1 'characterized by a great advantage in the format of j capsule packaging, which is not totally semi-spherical, allows the effective exit of the microvespas after hatching into it, 'since, due to its hexagonal prismatic shape, it prevents it from falling to the ground, II' h with all the ends of the exit of insects facing the soil, and therefore, partially or totally preventing the release of biological control agents. I ¹ 6. BIODEGRADABLE PACKAGE INTENDED FOR WRAPPING, ECLOSION AND DISTRIBUTION OF WASP EGGS AS A COMPLEMENT TO THE BIOLOGICAL CONTROL OF ?, ^r AGRICULTURAL AND GARDEN CROPS according to claims 1 and 2, i .í characterized by the use of a launch device (motorcycle equipped with a compressed air device or an unmanned aerial vehicle (Drone) allows the optimization and standardization of the dispersion process in the field, thus being an advantage over manual distribution. tl