CN107006434B - Biological container - Google Patents

Abstract

The present invention relates to a biocontainer comprising: the biological; the biological baffle is installed at the opening of each half shell, the space defined by each half shell and the biological baffle is a cavity for accommodating organisms, and the biological baffle is provided with an opening for the organisms to leave the defined space. The biocontainer of the present invention can ensure that the organisms are reliably administered.

Description

Biological container

Technical Field

The present invention relates to a biological container. In particular to a biocontainer which can be used in a biological dispenser, in particular a trichogramma.

Background

In agricultural production, the pest control is mainly carried out by pesticide control and biological control at present. In the pesticide control, an unmanned aerial vehicle is generally used for spraying chemical liquid medicine or sowing powder medicament to plants, and the like, and the method for controlling the insect pests has the following defects: the pesticide can cause environmental pollution and harm human health, and meanwhile, the pesticide has low utilization rate and is easy to be absorbed by plants. Today, where food safety is a common concern, the use of methods for biological pest control has become increasingly popular and of significant social significance.

At present, biological control methods mainly achieve the purpose of biologically controlling pests by manually hanging a biological container in which organisms or biological eggs are placed on a plant of a plant or by using an unmanned aerial vehicle loaded with a biological dispenser to deliver the biological container into a planting field of the plant or to hang the biological container on the plant of the plant.

The existing biological container capable of being matched with the unmanned aerial vehicle has the following defects: the biological container containing the organisms is not easy to open, and the opened biological container cannot be hung on a plant. In addition, some organisms need to be contained in the current biocontainers in an egg state, and after a period of time, the emerging organisms exit from the biocontainers. However, the existing biological container is easy to be completely opened to release the egg body in the release stage, or the emerged organisms are difficult to leave the biological container after the release, thereby affecting the operation effect of the unmanned aerial vehicle.

Disclosure of Invention

Problems to be solved by the invention

The technical problems in the prior art mentioned above are solved. The present invention provides an improved biocontainer, as described in detail below.

Means for solving the problems

The biocontainer according to the present invention comprises: the biological;

The biological baffle is installed at the opening of each half shell, the space defined by each half shell and the biological baffle is a cavity for accommodating organisms, and the biological baffle is provided with an opening for the organisms to leave the defined space.

Preferably, in the assembled state of the two half-shells, at least one gap is formed between the two half-shells, and the gap can be used for communicating the biological container with the outside air; and/or

The gap is for organisms to exit the biocontainer.

Preferably, be provided with first installation department on the opening edge of one of two half shells, be provided with the second installation department on the opening edge of another one of two half shells, first installation department with the second installation department can interengage to realize the aggregate erection of two casings.

Preferably, the first installation department sets up with the protruding mode of the opening edge of a relative half shell, the second installation department sets up with the recessed recess mode of the opening edge of another relative half shell, first installation department is with inserting the mode of second installation department is realized first installation department with the joint of second installation department.

Preferably, the first mounting portion is provided in plurality at an opening edge of the one half shell, and the gap along the opening edge is formed between the first mounting portions in a mounted state of the two half shells.

Preferably, the center of gravity of each of the half shells is located at the bottom of the half shells so that the half shells can be placed with their openings facing upward automatically in the above-mentioned separated state.

Preferably, a counterweight is arranged in each half shell or the bottom of each half shell is solid, so that the center of gravity of each half shell is located at the bottom of the half shell.

Preferably, the biological barrier projects above the opening in the half shell to direct liquid falling on the biological barrier to an area outside the biological barrier.

Preferably, a plurality of openings are arranged on the biological baffle at equal intervals; and/or

The biological baffle is provided with a connecting wire part for installing a connecting wire, and the connecting wire is used for connecting the two half shells.

Preferably, the half shells are hemispherical shells; and/or

The biological container is a trichogramma bee honeycomb.

A spherical biocontainer according to the present invention, comprising: the biological filter comprises two hemispherical shells, a biological filter body and a filter body, wherein the two hemispherical shells are combined to form a spherical shell, each hemispherical shell is provided with a cavity for accommodating organisms, and the spherical shell can be decomposed into the two hemispherical shells under the action of external force;

The biological baffle is arranged on the hemispherical surface side of the hemispherical shell and is provided with a hole for the organisms to leave the cavity.

The bottom of the spherical shell of the hemispherical shell is provided with a counterweight part.

The biological barrier has a central protrusion toward the outside of the cavity.

And the biological baffle plate is provided with an opening for installing the connecting wire.

The periphery of the hemispherical surface side of one hemispherical shell is provided with an installation ridge, the inner wall of the other hemispherical shell is provided with a groove for accommodating the installation ridge, and the two hemispherical shells are jointed to form the spherical shell by accommodating the installation ridge in the groove.

A gap for the organisms to leave the biological container is arranged between the two hemispherical shells which are combined to form the spherical shell.

The biological container is a trichogramma bee honeycomb.

ADVANTAGEOUS EFFECTS OF INVENTION

The biological baffle is adopted, so that the biological container can be divided into two independent half-shell spaces, the separated half-shells can bear impact, the integrity is ensured, and the organisms in the half-shells are protected. In addition, the opening arranged on the biological baffle plate enables the organisms to smoothly and freely leave from the separated half shells.

In at least one embodiment of the present invention, the biocontainer of the present invention can be easily disassembled and opened, and can be conveniently hung on a plant after opening.

In at least one embodiment of the present invention, the biocontainer of the present invention allows a living being to climb out of the gap of the biocontainer even in a state where it is not disassembled and opened, thereby achieving the goal of biological pest control.

In at least one embodiment of the present invention, the biological barrier of the biocontainer of the present invention protrudes above the opening of the half-shell, and can prevent water droplets and the like from entering the interior of the biocontainer.

In at least one embodiment of the invention, the center of gravity of each half-shell is located at the bottom of the half-shell, so that the half-shells can be placed with their openings facing upwards automatically in the separated state. The design of this structure makes half shell from the in-process that flies to fall in the air, guarantees half shell bottom down constantly, has avoided the biological baffle to land the condition that falls into the aquatic earlier.

In at least one embodiment of the present invention, the biological barrier of the biological container of the present invention is provided with a plurality of equidistantly disposed openings, which can ensure the air circulation of the biological container and allow the creatures inside the half shells to climb out.

In at least one embodiment of the present invention, the half shell of the present invention is a hemispherical shell, and the biocontainer of the present invention is a spherical shell assembled from two hemispherical shells. This spherical shell structure's design can make the bio-container conveniently walk on the track of dispenser to cooperation dispenser and unmanned aerial vehicle realize the efficient operation.

Drawings

FIG. 1 is a schematic view of the structure of a biocontainer of the present invention;

FIG. 2 is a schematic view of the opened biological container of the present invention;

FIG. 3 is a view showing the biological container of the present invention with the biological barrier omitted after opening;

FIG. 4 is a schematic view of the structure of the biological container of the present invention after being cut along a plane perpendicular to the biological baffle;

fig. 5 is a schematic view showing the structure of a biological barrier of the biological container of the present invention.

Description of the reference numerals

100-a biological container; 110-a first hemispherical shell; 111-a first hemispherical shell perimeter; 112-a separation connection; 113-a mounting ridge; 114-a first baffle mounting ring groove; 120-a second hemispherical shell; 121-the periphery of the second hemispherical shell; 122-housing mounting slots; 123-second baffle mounting ring groove; 130-connecting lines; 140-a biological barrier; 141-a cross-shaped opening; 142-a rectangular opening; 150-gap; 160-a first cavity; 170-a second cavity; 180-second cavity.

Detailed Description

The biocontainer of the present invention will be described and illustrated in detail below with reference to the accompanying drawings.

FIG. 1 is a schematic view showing the structure of the biocontainer of the present invention. Fig. 2 is a schematic view of the opened bio-container of the present invention. The biological container comprises two half shells and a biological baffle. In this embodiment, the biocontainer 100 of the present invention is preferably a spherical shell structure, and the two half shells are preferably a first half spherical shell 110 and a second half spherical shell 120. The design of the spherical shell structure is beneficial to the conveying and the walking of the biological container on the track of the dispenser. This embodiment preferably includes a connecting wire 130 and a biological barrier 140. The first and second hemispherical shells 110, 120 are preferably snap-fit joined. When the spherical shell structure is disassembled and opened, the first hemispherical shell 110 and the second hemispherical shell 120 are preferably connected by a connecting line 130. The connecting wire 130 can be used to suspend the first and second semispherical shells 110 and 120 from the plant.

Fig. 3 is a view showing the biological barrier of the present invention after the biological container is opened. FIG. 4 is a schematic view of the structure of the biological container of the present invention after being cut along a plane perpendicular to the biological barrier. In the assembled state of the two half-shells, at least one gap is formed between the two half-shells, and the gap is used for communicating the biological container with the outside air. The gap is for organisms to exit the biocontainer. Be provided with first installation department on the opening edge of one of two half shells, be provided with the second installation department on the opening edge of another half shell in two half shells, first installation department with the second installation department can interengage to realize the aggregate erection of two casings. The protruding mode of first installation department with the opening edge of a relative half shell is outstanding sets up, the recess mode that the second installation department is sunken with the opening edge of another relative half shell sets up, first installation department is with inserting the mode of second installation department is realized first installation department with the joint of second installation department. The opening edge of one half shell is provided with a plurality of first installation department, and under the mounted state of two half shells, it is a plurality of be formed with between the first installation department along the opening edge the clearance. Preferably, the first hemispherical shell periphery 111 of the hemispherical surface side of the first hemispherical shell 110 of the spherical shell structure has a plurality of separation connecting portions 112 extending along the spherical surface, and the outer wall of the separation connecting portions 112 is formed with a mounting rib 113 extending along the circumferential direction. The inner wall of the second hemispherical shell 120 is provided with a shell mounting groove 122 extending circumferentially. The distance from the mounting rib 113 to the first hemispherical shell periphery 111 is greater than the distance from the shell mounting groove 122 to the second hemispherical shell periphery 121. Therefore, when the first hemispherical shell 110 and the second hemispherical shell 120 are combined and the mounting rib 113 enters the shell mounting groove 122, a gap 150 is formed between the first hemispherical shell 110 and the second hemispherical shell 120. This clearance 150 can satisfy carrying out the circulation of air between the inside of spherical shell structure and the outside, and simultaneously, the biology in the spherical shell structure also can climb out spherical shell structure through this clearance 150 in order to realize the purpose of insect-attack prevention.

The spherical shell structure of the clamping connection can be easily decomposed by extrusion or collision. The biocontainer of the present invention can therefore be used in a biological dispenser capable of automated dispensing and hanging. This biological dispenser can hang in the unmanned aerial vehicle below to the plant protection operation is implemented in cooperation unmanned aerial vehicle.

A first baffle mounting ring groove 114 is formed in the inner wall of the first hemispherical shell 110 in parallel with the first hemispherical shell periphery 111. A second baffle installation ring groove 123 parallel to the second hemispherical shell periphery 121 is provided on the inner wall of the second hemispherical shell 120, and the shell installation groove 122 is located between the second hemispherical shell periphery 121 and the second baffle installation ring groove 123.

The biological baffle 140 is installed in the first baffle installation ring groove 114 of the first hemispherical shell 110, and a first cavity 160 is formed by the first hemispherical shell 110 and the biological baffle 140. The biological baffle 140 is installed in the second baffle installation groove 123 of the second hemispherical shell 120, and a second cavity 170 is formed by the second hemispherical shell 120 and the biological baffle 140. The first and second cavities 160 and 170 are used to hold organisms or biological eggs.

Fig. 5 is a schematic structural view of a biological barrier of the biological container of the present invention. The biological baffle protrudes above the opening of the half shell to direct liquid falling on the biological baffle to an area outside the biological baffle. The biological baffle is preferably provided with a plurality of the openings which are arranged equidistantly. The biological baffle is provided with a connecting wire part for installing a connecting wire, and the connecting wire is used for connecting the two half shells. Preferably, the biological barrier 140 is provided as a centrally raised disk-like structure. A cross-shaped opening 141 is provided at the center of the biological barrier 140, and the connection line 130 connects the first hemispherical shell 110 and the second hemispherical shell 120 through the cross-shaped opening 141. On the baffle 140, a plurality of openings 142 are provided around the cross-shaped opening 141. The openings 142 function to allow the first and second cavities 160 and 170 to communicate air with the outside. And when the biocontainer is placed in the field or hung on a plant, the creatures can climb out through the opening 142. When the biological barrier 140 is mounted on the hemispherical shell, the center of the biological barrier 140 protrudes toward the outside of the hemispherical shell. The design of the convex structure can prevent rainwater from dripping into the interior of the shell through the opening 142 to hurt organisms or organism eggs.

The center of gravity of each half-shell is located at the bottom of the half-shell so that the half-shells can be placed with their openings facing upwards automatically in the above-mentioned separated state. And a counterweight is arranged in each half shell or the bottom of each half shell is a solid body, so that the center of gravity of each half shell is positioned at the bottom of the half shell. Preferably, a weight 180 is provided at the bottom of each of the first and second hemispherical cases 110 and 120. The weight part 180 may be implemented by setting the bottom of the hemispherical shell to be a solid structure, or by installing a weight member at the bottom of the hemispherical shell. This counter weight portion 180 plays the counter weight effect at biological container's the in-process of puting in for biological container guarantees constantly that hemisphere casing bottom is down at the decline in-process, and biological baffle side is up. When water is accumulated in the plant growing field, the design can prevent the biological baffle plate 140 side of the biological container thrown into the plant growing field from falling into the water firstly. If the biological barrier side 140 of the biocontainer first falls into the accumulated water, the accumulated water may enter the interior of the first and second cavities 160 and 170 through the opening 142 and injure the organisms or biological eggs. Meanwhile, the weight portion 180 can play a role of a tumbler, and even if the biocontainer is soaked in water for a long time, the biocontainer can be ensured to be always upward from the side of the biological baffle.

Preferably, the biocontainer of the present invention is made of a degradable material, thus avoiding the burdensome work of recovering the residual hulls and causing no pollution to the environment and the farmland.

Although in the present embodiment, the bio-container is configured as a spherical shell structure, so that the bio-container can conveniently walk on the track of the dispenser during the dispensing process, thereby achieving efficient operation in cooperation with the dispenser and the drone, it should be understood that the bio-container of the present invention may be configured as a structure with other shapes, such as a cylinder.

The present embodiment will be further illustrated and described below by taking trichogramma as an example. The trichogramma can parasitize the corn borer, so the trichogramma can be used for preventing and controlling the corn borer insect pest. When trichogramma is used for biological control, trichogramma eggs are usually placed in a biological container, and then the biological container is placed in a corn field or hung on a corn plant. Accordingly, the biological container of the present invention may be described as a trichogramma bee hive hereinafter.

The trichogramma bee hive is provided as a spherical shell structure, for example, having a diameter of 3.9cm, including a first hemispherical shell 110, a second hemispherical shell 120, a connecting wire 130, and a biological barrier 140. The first hemispherical case 110 has three support curved surfaces extending along the spherical surface, and a mounting ridge 113 extending in the circumferential direction is formed on the support curved surfaces. The height of the mounting rib 113 is set to, for example, 2 mm. The inner wall of the second hemispherical shell 120 is provided with a shell mounting groove 122 extending circumferentially. The groove depth of the mounting groove 122 is set to 2mm, for example, accordingly. The distance from the mounting ridge 113 to the first hemispherical shell periphery 111 is about 1mm to 2mm greater than the distance from the shell mounting groove 122 to the second hemispherical shell periphery 121. Therefore, when the first hemispherical shell 110 and the second hemispherical shell 120 are combined and the mounting rib 113 enters the shell mounting groove 122, a gap 150 of 1mm to 2mm is formed between the first hemispherical shell 110 and the second hemispherical shell 120. Since the larvae of trichogramma are small, the gap 150 can satisfy the condition that the larvae of trichogramma climb from inside to outside the trichogramma bee hive shell to search for parasitic objects. In addition, the trichogramma bee hive can exchange air with the outside through the gap 150 to meet the air requirement of the trichogramma bee egg emergence process. In addition, since the depth of the mounting groove 122 is shallow, the portion of the mounting rib 113 that is caught in the mounting groove 122 is small, and the first and second hemispherical cases 110 and 120 can be easily disassembled and opened by pressing or collision.

The biological barrier 140 is provided as a centrally raised circular flap having a diameter of 3.5 cm. A cross-shaped aperture 141 is provided in the middle of the circular plate, and five rectangular openings 142 each having a length of 5mm and a width of 0.5mm, for example, are provided around the cross-shaped aperture 141. The five rectangular apertures 142 are arranged at equal intervals with the cross-shaped aperture 141 as a center, and the length direction of the rectangular apertures 142 is arranged in the radial direction of the circular flap. The first and second cavities 160 and 170 may exchange air with the outside through the five rectangular openings 142. When the trichogramma eggs in the first and second cavities 160 and 170 emerge as larvae, they can climb out through the five rectangular openings 142. The outward convex design of the center of the circular baffle can prevent water drops from flowing into the first cavity 160 and the second cavity 170, and the radial arrangement of the rectangular opening 142 along the circular baffle is beneficial to preventing water drops from flowing.

The connection line 130 is provided as a nylon wire having a length of 40 cm. The nylon thread connects the first hemispherical shell 110 and the second hemispherical shell 120 together through the cross-shaped opening 141 of the biological barrier 140.

The trichogramma comb is thrown by the biological throwing device, the trichogramma comb thrown by the biological throwing device is mostly decomposed into a first hemispherical shell 110 and a second hemispherical shell 120 which are connected by a connecting line 130 by the biological throwing device, the trichogramma comb is hung on a plant through the connecting line 130, and after trichogramma eggs become larvae, the trichogramma comb climbs out from a rectangular opening 142 of a biological baffle plate 140. The trichogramma bee hive which is not decomposed and opened is scattered in the corn field, and when the trichogramma egg feathers become larvae, it also climbs out from the gap 150 between the first and second hemispherical cases 110 and 120. Thereby achieving the aim of biological pest control.

The above description is only an embodiment of the present invention, but the scope of the present invention is not limited thereto, and any changes or substitutions that can be easily conceived by those skilled in the art within the technical scope of the present invention are included in the scope of the present invention.

Claims (8)

1. A biocontainer, said biocontainer comprising:

two half-shells, each half-shell has a cavity for accommodating biology, each half-shell has an opening, the openings of the two half-shells can be mutually jointed and combined to be installed into a shell, and the two half-shells jointed in the installation state are separated under the action of external force;

the biological baffle plate is arranged at the opening of each half shell, the space defined by each half shell and the biological baffle plate is a cavity for containing organisms, and the biological baffle plate is provided with an opening for the organisms to leave the defined space;

wherein, a first installation part is arranged on the opening edge of one of the two half shells, a second installation part is arranged on the opening edge of the other half shell of the two half shells, the first installation part and the second installation part can be mutually jointed, thereby realizing the combined installation of the two shells,

The protruding mode of first installation department with the opening edge of a relative half shell is outstanding sets up, the recess mode that the second installation department is sunken with the opening edge of another relative half shell sets up, first installation department is with inserting the mode of second installation department is realized first installation department with the joint of second installation department.

2. The biocontainer of claim 1, wherein in the assembled state of the two half shells, at least one gap is formed therebetween for the air communication of the biocontainer with the outside; and/or

The gap is for organisms to exit the biocontainer.

3. The biocontainer of claim 2, wherein a plurality of the first mounting portions are provided at the opening edge of the one half-shell, and the gap along the opening edge is formed between the plurality of first mounting portions in the mounted state of the two half-shells.

4. The biocontainer of claim 1, wherein the center of gravity of each half shell is located at the bottom of the half shell so that the opening of the half shell can be placed in an automatically upward manner in the separated state.

5. The biocontainer of claim 4, wherein a weight is disposed within each of the half shells or a bottom portion of each of the half shells is solid such that a center of gravity of each of the half shells is located at the bottom portion of the half shell.

6. The biocontainer of claim 1, wherein the biological barrier protrudes above the opening of the half shell to direct liquid that falls on the biological barrier to an area outside of the biological barrier.

7. The biocontainer of claim 1, wherein said biological barrier has a plurality of said openings disposed therein at equal distances; and/or

The biological baffle is provided with a connecting wire part for installing a connecting wire, and the connecting wire is used for connecting the two half shells.

8. The biocontainer of any one of claims 1-7, wherein the half shell is a hemispherical shell; and/or

The biological container is a trichogramma honeycomb.

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