ES2970043B2 - TRAP FOR BEETLES IN PALM TREES - Google Patents

Description

DESCRIPTION

TRAP FOR MONITORING AND CAPTURING BELEOPTERANS IN PALM TREES

PURPOSE OF THE INVENTION

The present invention refers to a beetle trap that is installed in palm trees, including tall ones, so the object of the invention is to provide a device for monitoring and/or controlling pests of this type of insect, this being a device of small dimensions, easy to install, great stability and durability, which must be installed between the rings of green leaves of the valance of the palm trees.

The scope of the invention is within the industrial sector related to pest control equipment and systems and, specifically, it falls within the different types of traps intended for monitoring and mass capture of beetles in palm trees. Going into greater detail, the trap is especially designed for monitoring and mass capture of the beetle Diocalandra frumenti (Fabricius), commonly known as the four-spotted coconut weevil.

BACKGROUND OF THE INVENTION

There are numerous arthropod pests that affect palm trees, including various species belonging to the Coleoptera Order, and specifically those included in the Curculionoidea superfamily. The weevils are characterized by being mostly phytophagous, feeding on stems, leaves, roots, fruits, among others; this, together with their voracity, adaptability, high reproduction rate and potential for dispersal, make them important pests of agricultural, forestry or ornamental plants.

The present invention is specially designed for the monitoring and mass capture of beetles, and more specifically for the species Diocalandra frumenti (Fabricius) (Coleoptera: Dryophthoridae) or four-spotted coconut weevil, also known in the Canary Islands as the "palm weevil".

Adults are small, about 6-8 mm long, with an elongated body and generally reddish-brown to black in colour, with black markings on the pronotum and clear markings on the elytra. It is native to south-east Asia and is found throughout the tropics in various coastal areas of the Pacific and Indian Oceans.

Diocalandra frumenti adults are attracted to a palm tree by sap exuding from a wound or the base of flowers, or by cuts in leaves during pruning or tearing by strong winds. Females may lay eggs in inflorescences, at the base of petioles or peduncles or in cracks near adventitious roots at the base of the stipe. When the larvae hatch, they excavate galleries in any part of the palm tree, feeding on the young tissue through which the sap circulates to the palm leaflets, where photosynthesis takes place. They develop entirely inside the palm tree. Pupation takes place inside the gallery excavated by the larva, without forming a cocoon.

The main damage caused by Diocalandra frumenti occurs during its larval stage. To feed, the larvae dig galleries 1-2 mm in diameter in healthy tissues of the basal third of the rachis of green leaves, producing gummy exudations and causing premature drying and collapse of leaves in the crown of the palm tree, starting from the outer leaves towards the inner leaves. In addition, Diocalandra frumenti is attributed indirect damage, which is that it acts as a vector in the spread of fungal diseases caused by opportunistic fungi, or constitutes the entry route for phytopathogenic fungi that are lethal to the palm tree.

This insect has been detected in at least 17 genera of the Arecaceae family, most of which are economically important palm species, cultivated for their food or ornamental value. Its main hosts are the coconut palm (Cocos nucifera L.) and the Canary Island date palm (Phoenix canariensis) and their hybrids. Other less important hosts are the date palm (Phoenix dactylifera L.), the oil palm (Elaeis guineensis Jacq.), the nipa palm (Nypa fruticans Wurmb) and many other ornamental palms. These hosts are shared with another important pest that affects palm trees, known as the red palm weevil (Rhynchophorus ferrugineus Olivier), a larger beetle, which also causes very serious consequences in most palm species.

Diocalandra frumenti first appeared in Europe in 1998 on the island of Gran Canaria (Canary Islands), associated with damage to P. canariensis, P. dactylifera and their hybrids, and isolated specimens of C. nucífera and Washingtonias spp. The EPPO expert committee indicated that the route of entry of Diocalandra frumenti was through the importation of nursery palms from countries where the pest was present. Although there is no data on the natural dispersal of Diocalandra frumenti, it is known that adults can make short flights, which is of particular importance in plant nurseries, constituting one of the main routes of dispersal of the pest. In addition, there is a potential risk of dispersal of Diocalandra frumenti from its current distribution area to other regions where the palm is cultivated, due to the fact that the climatic conditions are moderately similar, according to the Koppen-Geiger climate classification.

As for the control methods of Diocalandra frumenti, it is recommended to carry out preventive or cultural measures aimed at avoiding or reducing the incidence of this pest in palm trees. In addition, there are several biological control strategies that can be effective in controlling Diocalandra frumenti in palms: a) natural enemies such as larval parasitoids (Spathius apicalisWestwood (Hymenoptera: Braconidae) andSclerodermas pp. (Hymenoptera: Bethylidae)) and predators (Plaesius javanusErichson (Coleoptera: Histeridae) andChrysopilus ferruginosusWiedemann (Diptera: Rhagionidae)); b) among the entomopathogenic fungi, the high potential of Beauveria bassiana(Bals.) Vuill to infect and cause high mortality stands out. (Moniliales: Deuteromycetes) and Metharhizium anisopliae (Metschnikoff) Sorokin (Ascomycota: Hypocreales) and c) the entomopathogenic nematode Steinernema feltiae Filipjev (Rhabditida: Steinernematidae), with a high capacity to search for and locate the host, attributes that make them an alternative to consider in the control of pests in palm trees.

As for chemical control, phytosanitary products have traditionally been the main tool for controlling arthropod pests, however, these products are not free of risks to health and the environment, so in recent decades, and following the entry into force of Directive 2009/128 / EC for the sustainable use of phytosanitary products, the application of Integrated Pest Management (IPM) programs has been promoted, which give priority to alternative approaches or techniques to chemical ones, such as biological, cultural and biotechnological methods, using chemical methods as a last resort. Currently, there are no products authorized in the registry of phytosanitary products of the Ministry of Agriculture, Fisheries and Food for the control of Diocalandra frumenti.

From the GIP approach, the use of a trapping system for monitoring and mass capture of Diocalandra frumenti is a key biotechnological tool for controlling populations of this beetle, for which it is necessary to have an appropriate attractant and trap.

To date, the chemical compound involved in the aggregation pheromone of Diocalandra frumenti is known and is described in document ES2638713 and identified as 5-ethyl-2,4-dimethyl-6,8-dioxabicyclo[3.2.1]octane (multistriatin). The Diocalandra frumenti pheromone is currently commercially available, constituting a technological innovation that is respectful of human health and the environment. In addition, said document details the method for monitoring Diocalandra frumenti populations and the method for preventing damage to palm trees caused by this species; however, no mention is made of the trap that must be associated with this attractant.

In the bibliographic review carried out, no records of traps that meet the necessary requirements for the capture of Diocalandra frumenti have been detected.

For all the reasons mentioned above, the present invention consists of a trap for the monitoring and mass capture of Diocalandra frumenti, baited with pheromonal and kairomonal attractants and housed in the palm tree between the first rings of green leaves of the valona. The trap can be used for the monitoring of the pest, providing very valuable information by placing only 2-3 traps per hectare; which will allow the pest to be detected, the level of infestation to be assessed, the population dynamics of the pest to be established and the ideal time to carry out phytosanitary treatments to avoid unnecessary treatments to be established. In addition, the trap can be used for mass capture by placing a high density of traps to capture the greatest number of insects possible, where the insect dies by drowning or being captured due to the trap's own architecture.

EXPLANATION OF THE INVENTION

The trap, object of the present invention, consists of three bodies:

- An upper body, with an internal housing for the pheromonal attractant, comprising at least two holes, facing each other, which allow the diffusion of the attractant and the access of the insect;

- A middle body, housing the kairomonal attractant, and inside which the mechanism for actuating the blades by means of a spring is housed, which allows the trap to be anchored to the palm tree. The arrangement and length of the blades can be variable. The body comprises at least two holes that allow the diffusion of the kairomonal attractant and the access of the insects; in which cones can be installed to make it difficult for the insects to exit the trap. These cones are made of a porous mesh, with at least 1 mm of pore, so as not to interfere with the flow/diffusion mechanics of the attractant; - A basal body, with a minimum capacity of 1,000 ml, where the hydrogel is dispensed, hydrophilic, soft and elastic polymers that swell in the presence of water, considerably increasing their volume and releasing the necessary water in the trap in a controlled manner. The hydrogel also has a retentive effect on the insects captured in the trap. This body comprises at least two holes that allow the aeration and release of the water contained in the hydrogel, as well as the access of insects. Cones made of a porous mesh, with a pore of at least 1 mm, can be installed in these holes so as not to interfere with the flow/diffusion mechanics of the attractant substance, which allow the passage of a small beetle, but make it difficult for it to leave.

The assembly of the different bodies is done by means of coupling, which can be by tightening, by clipping, or by threading. In a preferred embodiment of the invention, it is done by threading, and specifically, the lower mouth of the upper body and the upper mouth of the middle body are fixed by means of a threaded coupling; and where the lower mouth of the middle body and the upper mouth of the basal body are fixed by means of a threaded coupling.

This trap configuration is primarily designed for the capture of Diocalandra frumenti, although it can be used for other types of beetles. In this sense, the anchored arrangement in contact with the palm leaves through the lateral blades allows the insects to have direct access to the trap, either by walking or by making short flights from the leaf.

The material and/or dimensions of the different parts that make up the trap are not intended to be protected, although in a possible embodiment of the invention, the material used is polylactic acid plastic (PLA), which is a biodegradable polymer obtained from corn starch; however, it can be made from any other type of material.

The present invention is suitable for capturing this type of insects (coleoptera), and has the following advantages:

- It is completely recyclable as it is made from a biodegradable polymer. - It has a low visual impact design, with colours that blend perfectly with the palm tree.

- It does not use insecticides as retentives for Diocalandra frumenti adults, and this fact means that it can be included in the Register of certain phytosanitary defence means (MDF) as it is not considered a phytosanitary product.

- The trap is hung and lowered from the palm tree using a telescopic pole, which considerably reduces the time spent on this action and the risk to the operator by not working at height. - By using hydrogels, a retentive effect has been achieved and, in addition, the service period of the trap in the field has been increased by a period of at least two months.

It should be noted that the terms used in this specification are to be taken in a broad and non-limiting sense, and the specific definition of the measurements, shapes or materials of the different elements that make up the press is not the object of the invention; just as the description of how to put it into practice must be taken in a broad and non-limiting sense.

BRIEF DESCRIPTION OF THE PLANS

To illustrate the description of the invention, a set of non-limiting drawings representing the following is attached as an integral part thereof:

- Figure 1. Front view of the assembled trap.

- Figure 2. Side view of the assembled trap.

- Figure 3. Front view of the trap with the components exploded, allowing us to see what internal elements the trap comprises.

- Figure 4. Side view of the trap with the components exploded.

DETAILED DESCRIPTION OF THE MODE OF CARRYING OUT THE INVENTION

Based on what has been previously described and the figures previously indicated, the trap object of the present invention has the particularity of comprising:

- An upper body (1), which includes a basket (2) and the support (3) thereof to house the pheromonal attractant, which comprises at least two upper holes (4), facing each other, which allow the diffusion of the attractant and the access of the insect;

- A middle body (5), with housing for a container (6) where the kairomonal attractant is dispensed, and inside which the mechanism for actuating the blades (7) by means of a spring is housed, which allows the anchoring of the trap to the palm tree. The arrangement and length of the blades can be variable. The body comprises at least two intermediate holes (8) that allow the diffusion of the kairomonal attractant and the access of the insects; in which intermediate cones (9) can be installed to make it difficult for the insects to exit the trap. These cones are made of a porous mesh, with at least 1 mm of pore, so as not to interfere with the flow/diffusion mechanics of the attractant; - A basal body (10), with a minimum capacity of 1,000 ml, where the hydrogel is dispensed, hydrophilic, soft and elastic polymers that swell in the presence of water, considerably increasing their volume and releasing the necessary water into the trap in a controlled manner. The hydrogel also has a retentive effect on the insects captured in the trap. This body comprises at least two lower holes (11) that allow the aeration and release of the water contained in the hydrogel, as well as the access of the insects. In said holes, lower cones (12) made of a porous mesh, with a pore of at least 1 mm, can be installed so as not to interfere with the flow/diffusion mechanics of the attractant substance, which allow the passage of a small beetle, but make it difficult for it to exit. - Where the lower mouth of the upper body and the upper mouth of the middle body are fixed together by means of a coupling (13) that is threaded; and where the lower mouth of the middle body and the upper mouth of the basal body are fixed together by means of a coupling (14) that is threaded.

Claims (11)

1. - Trap for monitoring and capturing beetles in palm trees, baited with pheromonal and kairomonal attractants and placed in the palm tree between the first rings of green leaves of the valona. The trap is characterized by comprising: - An upper body (1), which includes a basket (2) and the support (3) thereof to house the pheromonal attractant, which comprises at least two upper holes (4), facing each other, which allow the diffusion of the attractant and the access of the insect; - A medium body (5), with housing for a container (6) where the kairomonal attractant is dispensed, and inside which is housed the mechanism for actuating the blades (7) by means of a spring, which allows the trap to be anchored to the palm tree. - A basal body (10), with a minimum capacity of 1,000 ml, where the hydrogel is dispensed. This body comprises at least two lower holes (11) that allow the aeration and release of the water contained in the hydrogel, as well as the access of the insects. In said holes, lower cones (12) made of a porous mesh, with a pore of at least 1 mm, can be installed so as not to interfere with the flow/diffusion mechanics of the attractant substance, which allow the passage of a small beetle, but make it difficult for it to exit. - Where the lower mouth of the upper body (1) and the upper mouth of the middle body (5) are fixed together by means of a coupling (13) that is threaded; and where the lower mouth of the middle body and the upper mouth of the basal body are fixed together by means of a coupling (14) that is threaded. 2. - Trap for monitoring and capturing beetles in palm trees, according to claim 1, wherein the basket (2) is fixed to the upper body by means of a support (3). 3. - Trap for monitoring and capturing beetles in palm trees, according to claim 1, where the intermediate access holes (8) of the middle body face each other. 4. - Beetle trap in palm trees according to claim 1, wherein the intermediate access holes (8) of the middle body comprise an intermediate cone (9) made of a porous mesh. 5. - Trap for monitoring and capturing beetles in palm trees, according to claim 4, wherein the mesh for manufacturing the intermediate cones (9) has pores of at least 1 mm in diameter. 6. - Trap for monitoring and capturing beetles in palm trees, according to claim 1, where the lower access holes (11) of the basal body face each other. 7. - Trap for monitoring and capturing beetles in palm trees, according to claim 1, wherein the lower access holes (11) of the basal body comprise a lower cone (12) made of a porous mesh. 8. - Trap for monitoring and capturing beetles in palm trees, according to claim 7, wherein the mesh has pores of at least 1 mm in diameter. 9. - Trap for monitoring and capturing beetles in palm trees, according to claim 1, where the mechanism for driving the blades (7) is activated by a telescopic pole in the tasks of hanging and lowering the trap in the palm tree. 10. - Use of a trap as defined in any of the preceding claims for monitoring and capturing beetles in palm trees. 11. - Use of a trap according to claim 10, wherein the beetles are specimens of the species Diocalandra frumenti.