CONTAINER FOR TRANSPORTING AND INOCULATING PUPAE

Abstract

The invention refers to a container (1) that can be used for storing, transporting and for inoculating silk-free pupae. The container (1) comprises a tray (2) having a substantially flat surface (5) and a plurality of wells (4) formed on the surface (5), wherein each well (4) configured for accommodating a pupa (8). The container (1) also comprises a lid (3) having a plurality of openings (6), wherein the tray (2) and the lid (3) are configured to be coupled to each other, such as the lid (3) is placed on the flat surface (5), at least partially, closing the wells (4). The wells (4) and the openings (6) are arranged, such as when the tray (2) and the lid (3) are 10 coupled together, each well (4) is accessible through an opening (6). The container is stackable for an optimum and cost-efficient secure transportation.

Claims

1. A container for transporting and inoculating pupae, comprising: a tray having a substantially flat surface and a plurality of wells formed on the surface, each well of the plurality of wells configured for accommodating a pupa, and a lid having a plurality of openings, wherein the tray and the lid are configured to be coupled to each other, wherein when the lid is placed on the flat surface, at least partially, closing the plurality of wells, wherein the plurality of wells and the plurality of openings are arranged, when the tray and the lid are coupled together, each well is accessible through an opening, and wherein the tray and the lid are provided with interlocking means to mechanically retain the tray and lid engaged.

2. The container according to claim 1, wherein the container is configured as a stackable container in such a way that two or more containers are stackable on top of each other, by inserting a top part of the container from below at least partially in the tray of another container, and wherein an air chamber is formed between each pair of consecutive stacked containers, wherein the plurality of wells of the same container are in fluid communication.

3. The container according to claim 2, wherein the container is further configured to define ventilation passageways between stacked containers, and wherein the ventilation passageways fluidly are in fluid communication with the air chambers and an exterior environment, wherein each well is in fluid communication with the exterior environment through the ventilation passageways.

4. ContainerThe container according to claim 3, wherein the ventilation passageways comprise overlapping ventilation openings formed in the lid and the tray of the container and/or wherein the ventilation passageways are formed laterally between the stacked containers.

5. The container according to claim 1, wherein the tray and the lid have a frusto-pyramidal configuration, and wherein the tray has a base defining the flat surface and having four sides and lateral walls transversally projecting from the base and extending along the four sides of the base, and wherein the lid has a base having four sides and a-lateral walls transversally projecting from the base and extending along the four sides of the base, and wherein when the tray and the lid are coupled, their bases and lateral walls overlap.

6. The container according to claim 1, wherein the plurality of wells and the plurality of openings are distributed in columns and rows configuring an orthogonal matrix.

7. The container according to claim 1, provided with an information code having information for tracking the container ad/or for inoculating the pupae.

8. The container according to claim 7, wherein the information code is an electronically, electromagnetically or optically readable code.

9. The container according to claim 7, further comprising a Radio Frequency Identification (RFID) tag containing the information code.

10. The container according to claim 1, wherein each well is elongated and has generally a frusto-pyramidal configuration with a concave bottom surface.

11. The container according to claim 1, wherein the tray and/or the lid include reinforcing means to structurally reinforce the tray and/or the lid respectively.

12. The container according to claim 5, wherein the interlocking means are provided at the lateral walls of the tray and the lid, and they are configured as male and female snap-fitting members.

13. The container according to claim 1, wherein the tray and the lid have been obtained by thermoforming a plastic sheet.

14. The container according to claim 11, wherein the reinforcing means comprises at least one groove at a base of the tray and at least one groove at a base of the lid, wherein the at least one groove is recessed respectively from the base of the tray and the base of the lid, and wherein the least one groove extends transversally to the tray and lid, and they are arranged to overlap when the tray and the lid are coupled.

15. A set of stacked containers comprising the stacked containers as claimed in claim 2, wherein ventilation passageways are formed laterally between each pair of consecutive stacked containers, and wherein the ventilation passageways are formed by fluid communication of air chambers formed by each pair of consecutive stacked containers.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0027] Preferred embodiments of the invention are henceforth described with reference to the accompanying drawings, wherein:

[0028] FIG. 1—shows a perspective view from above of a preferred embodiment of the container of the invention, wherein the tray an lid are shown uncoupled.

[0029] FIG. 2—shows a perspective view from below of the same embodiment of FIG. 1.

[0030] FIG. 3—shows a perspective view from below of the lid.

[0031] FIG. 4—shows a top plan view of the tray.

[0032] FIG. 5—shows a top plan view of the lid and tray coupled together.

[0033] FIG. 6—shows a cross-sectional elevational view taken at plane A-A in FIG. 5.

[0034] FIG. 7—shows a cross-sectional elevational view along plane B-B in FIG. 5.

[0035] FIG. 8—shows a perspective view of the tray and lid coupled together.

[0036] FIG. 9—shows a front elevational view of the tray and lid coupled together.

[0037] FIG. 10—shows a cross-sectional elevational view of several stacked containers, and an enlarged detail of the containers wherein the air circulation between stacked containers is indicated by arrows.

[0038] FIG. 11—shows a perspective view of a container in use while it is placed at a compatible baculovirus vector inoculation robot.

PREFERRED EMBODIMENT OF THE INVENTION

[0039] As shown in FIG. 1, a container (1) according to the invention comprises a tray (2) and a lid (3) that can be coupled to each other for storing and transporting pupae. The tray (2) has flat surface (5) and a plurality of wells (4) formed on the surface (5) wherein each well (4) is configured for receiving and retaining a pupa.

[0040] The lid (3) has a flat surface (7) with a plurality of openings (6) that are arranged in correspondence with the position of the wells (4) in the tray, so when the tray (2) and the lid (3) are coupled together, the lid (3) partially close the wells (4) enclosing the pupae, and each well (4) is accessible through an opening (6), as shown for instance in FIG. 10.

[0041] As shown in FIGS. 4 and 5, preferably the wells (4) and the openings (6) are distributed in columns and rows configuring an orthogonal matrix.

[0042] The internal shape of each well (4) is shown in FIGS. 5, 6 and 10. More specifically, each well (4) is an elongated receptacle with generally a frusto-pyramidal configuration, having: a concave bottom surface, an inclined lateral surface and an open upper base. This internal shape of each well (4) has the advantage that a pupa (8) is retained in a fixed position relative to the corresponding opening (6) right over the well (4), through which a needle would be inserted during the inoculation process, thereby preventing any undesired displacement of the pupa (8) while the needle penetrates a pupa.

[0043] The tray (2) has a rectangular base (11) defining the flat surface (5) where the wells (4) are formed, and four lateral walls (12a,12b,12c,12d) respectively at each of the four sides of the base (11), and projecting transversally from the base (11). Similarly, the lid (3) has a rectangular base (21) and four lateral walls (13a,13b,13c,13d) projecting transversally respectively from each of the four sides of the base (21).

[0044] Both, the tray (2) and the lid (3) have frusto-pyramidal configuration, shaped and dimensioned to the coupled together as shown for example in FIGS. 6 and 7, so when they are coupled, the bases (5,21) and lateral walls (12a,13a,12b,13b,12c,13c,12d,13d) overlap.

[0045] In order to securely retain the tray and lid engaged during storage and transportation, the tray (2) and the lid (3) are provided with co-operating interlocking means (9,10) located at the lateral walls (12a,13a,12b,13b, 12c, 13c, 12d, 13d) of the tray (2) and the lid (3). In this preferred embodiment, the interlocking means are configured as male (9) and female (10) snap-fitting members of complementary shape, that are integrally formed respectively with the tray (2) and the lid (3) and provided nearby the four corners of the container (1). For coupling the tray and the lid, these male (9) and female (10) snap-fitting members are pressed together, until the male member (9) engages with the female member (10).

[0046] As represented in FIG. 10, the container (1) is configured to be stackable by inserting a top part of a container in the tray of another container.

[0047] An air chamber (18) is formed between each pair of consecutive stacked containers (1) fluidly communicated the wells (4) of the same tray (1). The containers (1) are additionally configured to define ventilation passageways (17) between stacked containers (1) as shown in FIG. 10, wherein the ventilation passageways (17) fluidly communicate the air chambers (18) with the exterior environment, so each well (4) is fluidly communicated with the exterior environment through the ventilation passageways (17).

[0048] Additionally, additional ventilation passageways comprises overlapping ventilation openings (16,16′) formed in the lid (3) and the tray (2) of the container when a lid and tray are coupled.

[0049] Furthermore, the container (1) is provided with an information code containing data and instructions for tracking the pupae incorporated into the container and/or for inoculating the pupae. This code is an electronically, electromagnetically or optically readable code. Preferably, the code is stored in a Radio Frequency Identification (RFID) tag (14) attached to the tray (3), for example glued within a recess (15) formed in the tray (3), and closed by the lid (3), so that the tag (14) is readable through the lid (3). The code preferably include information like: pupae expiration date, inoculation data, tracking number.

[0050] The tray and/or the lid include reinforcing means to structurally reinforce the tray and/or the lid respectively. These reinforcement means comprise at least one channel or groove (19,19′) at the base (11) of the tray (2), and at least one channel or groove (20,20′) at the base (21) of the lid (3). The grooves (19,19′, 20, 20′) are recessed respectively from base (11) of the tray (2) and the base (21) of the lid (2), and they extend transversally to the tray and lid, and are arranged such as when the tray and the lid are coupled, the grooves (20,20′) of the lid (3) are received inside the grooves (19,19′) of the tray (2) as shown in FIG. 7.

[0051] Reinforcing grooves (21,22) are also formed at the lateral walls (12a,13a,12b,13b,12c,13c,12d,13d) of the tray (2) and the lid (3).

[0052] In a preferred embodiment, the tray (2) and the lid (3) are conventionally obtained by thermoforming respective sheet of suitable plastic material.

[0053] FIG. 11 shows a container (1) in use while it is placed at a compatible robot (24) for inoculating the pupae inside the container with a baculovirus vector (1). The inoculation robot (24) includes an inoculation unit (23) that it is displaceable to specific locations according to the matrix distribution of the holes above the pupae, to be inoculated by means of a needle (not shown) installed at the inoculation unit (23). The inoculation unit is connected with a precision pump dispensing the desired volume of the baculovirus vector into the pupae.

[0054] The inoculation robot (24) additionally incorporates a reading unit (25) adapted for reading an information code provided in the container (1), in this case a (RFID) tag, so that, the information contained in the code such as: pupae expiration date, inoculation instructions data, and/or container tracking number, is loaded at the inoculation robot (24).