SMART INSECT TRAP

Abstract

This invention relates to an intelligent insect trap, which allows a simple and effective monitoring of the insects captured inside the trap. It consists of a cylindrical or prismatic housing with a perimetral entrance accessing to an usable internal surface positioned in the active state/mode. This surface is adhesive and located near a container that holds a semiochemical lure. The trap also includes one or more video or photo cameras oriented towards the active sticky surface. Additionally, the trap comprises two or more adherent surfaces, which are mobile along the housing, preferably in the form of a disc or ring, and configured to be consecutively positioned in the active state.

Claims

1. Intelligent insect trap, with a cylindrical or prismatic housing (1) that has a perimeter entrance (2) allowing the access to an internal active adhesive/sticky usable surface (3), and a container (7) holding a semiochemical lure, one or more cameras (4) oriented toward the active usable surface (3), and a battery, the upper part of the cylindrical or prismatic housing can store two or more adhesive surfaces (3), which are mobile along the housing (1), configured to be positioned consecutively in the active state.

2. Intelligent insect trap, according to claim 1, characterized by a housing support (5) holding one or more adjustable photovoltaic plates (6) for battery recharging, not limited to the photovoltaic plate being housed on top of the housing (1).

3. Intelligent insect trap, according to claim 1, characterized by including a communication system with a computer server.

Description

BRIEF DESCRIPTION OF DRAWINGS

[0010] To complement this description and to aid in a better understanding of the unique invention's features, a set of drawings is provided as an illustrative and non-limiting example, representing the following:

[0011] FIG. 1: Schematic view of an example of the invention.

[0012] FIG. 2: Exploded view drawing of the main parts of the previous example.

[0013] FIG. 3: Example of the base-changing system using a servomotor.

[0014] FIG. 4: Example of the method for moving the bases consecutively. (A) dropping the lowest base while retaining the others; (B) retaining all bases.

[0015] FIG. 5: Circular base containing adhesive/sticky surface for insect capture.

BEST MODE FOR CARRYING OUT THE INVENTION

[0016] Below, an example of an implementation of the invention is described briefly, as an illustrative and non-limiting example of it.

[0017] FIG. 1 shows a general view of the trap according to an implementation. It includes a cylindrical housing (1) with a perimeter entrance (2) formed by a removable grid. Inside the housing (1), a container (7) holds the semiochemical specific to the insect to be attracted, along with a series of bases (3) in the form of discs or rings, with adhesive on their usable surfaces. One of the surfaces (3), referred to as active, exposes its adhesive/sticky surface to the entrance (2), while the rest are hidden by it or other surfaces (3). The unused and inactive surfaces are stored at the top of the housing (1) and can be moved to the active position when the user remotely activates the change system with the servomotor (12).

[0018] One or more cameras (4) are oriented toward the active surface. The camera (4), typically one, can store images until they are manually retrieved or sent by an appropriate method to a computer server. For instance, through a SIM card, a LoRa communication system, Wi-Fi, etc., with the appropriate and required range.

[0019] For example, the surfaces (3) can have a central hole, so the camera (4) aligns with that central hole (FIG. 2). Thus, the two elements do not interfere with each other.

[0020] In use, insects are attracted inside by the specific semiochemical within a container (7), and they adhered/trapped on the active sticky surface (3). Once the active sticky surface (3) is considered saturated with insects or a reset is desired, the servomotor (12) moves an inactive surface (3) stored at the top of the housing (1) to replace the used active surface (3). This process moves a new surface (3) into the active position, covering the previously used one. For example, the surfaces (3) descend by gravity into the active position, using the mechanism illustrated in FIG. 3. In this figure, two claws (13, 14) perform alternating movements to sequentially release the bases (3). The two claws (13, 14) have spikes that hold the bases (3). The upper claw (14) separates the lowest surface from the rest, while the lower claw (13) releases the bottom base to activate it (FIG. 3A). In FIG. 3B, all surfaces are retained.

[0021] Another embodiment, shown schematically in FIG. 4, involves the surfaces (3) being interlocked by an alignment pin (31), for instance, in the slot of a variably pitched worm screw (11), which allows the surface (3) moves down at different speed. At one end, for storage, the pitch distance is narrow, so the surfaces (3) are close to each other (top in FIG. 4). At the active surface (3) area, the pitch distance is wider, allowing the base to move faster into the working position while the previous surfaces barely move. When a surface change (3) is desired, the worm screw continues turning, advancing the new surface (3) through the large pitch area, while the used surface moves down through a small pitch area, covered by the new or falls by gravity into a container. In another embodiment, the active surface (3) area lacks the screw, allowing it to fall by its weight. Consequently, a gap opens for insect access to the usable surface.

[0022] FIG. 5 shows an exploded drawing of a surface (3). It includes an adhesive ring-shaped sheet (32), an inner reinforcing ring (33), and several peripheral clamps (34). The clamps (34), among other functions, separate the surfaces (3) from each other.

[0023] The trap housing (1) can be attached to a pole by mounting clamps (5). On top of the trap housing one or more photovoltaic plates (6) can be set for recharging the battery that powers the entire trap. This allows the photovoltaic plates (6) to be oriented independently of the trap (1) position or orientation. A power on/off button cage (8) manages the trap by powering the electronic controller (10), which manages and control all the electronic devices (servomotor, sensors, camera, etc.) of the trap.

[0024] Additionally, it includes humidity and/or temperature sensors (9), as known from the cited state of the art, but not limited exclusively to sensors for these two parameters.