CN114847213A - Hierarchical breeding device, hierarchical breeding device group and breeding tower - Google Patents

Abstract

The invention mainly discloses a hierarchical breeding device, which comprises: a pond farm is separated the module with N, N is separated the module and is in divide N +1 cultivation district in the pond farm. According to the design of the invention, the separation module can change the space of the culture areas by moving forwards and backwards, so that the N +1 culture areas have different space sizes. Therefore, when the stratified culture apparatus of the present invention is used, stratified (Class division) culture can be realized in accordance with the staged volume growth of the aquatic animals to be raised in captivity. Meanwhile, the invention makes an effective hierarchical partition in an accommodating space of the pool farm, so that the utilization rate of the whole accommodating space of the pool farm can be optimally configured.

Description

Hierarchical breeding device, hierarchical breeding device group and breeding tower

The technical field is as follows: the invention relates to the technical field of aquaculture cultivation, in particular to a hierarchical cultivation device and an intelligent cultivation system. .

Background art:

aquaculture (or aquaculture fishery) is to breed young seedlings of aquatic animals (such as fishes and shrimps) with high economic value by using a natural pond farm or an artificial pond farm, and to remove diseases for the young seedlings, so that the young seedlings grow rapidly. According to the different water quality of cultivation, the method can be divided into three categories of fresh water cultivation, salt water cultivation and sea surface cultivation.

Fig. 1 is a perspective view of a known artificial pond. As shown in fig. 1, the artificial pond farm 1a includes a first cultivation area 11a and a second cultivation area 12a, and the first cultivation area 11a and the second cultivation area 12a are separated by a spacer 1 Sa. Wherein, the first cultivation area 11a is used for cultivating seedlings of aquatic animals in captivity, and after the seedlings grow to a predetermined degree, the seedlings are transferred to the second cultivation area 12a for continuous captivity. In the prior art, the spacer 1Sa may be a partition, a partition wall, or a net for realizing a fixed separation between the first cultivation area 11a and the second cultivation area 12 a. Fixed partitioning means that elastic adjustment is not possible.

Thereafter, when the body of the young seedling is large to a predetermined degree, the farmer must hire a lot of manpower to quickly and efficiently transfer the aquatic animals stocked in the first culture section 11a to the second culture section 12a, thereby separating the aquatic animals stocked in the small-sized section. Unfortunately, the transfer work by a large amount of manpower is time-consuming and laborious, and it is difficult to realize the layered (Class division) rearing according to the staged growth of the captive aquatic animals.

From the foregoing description, it can be seen that the existing artificial pond (or artificial cultivation device) still has the need for improvement. In view of the above, the present inventors have made extensive studies and finally developed a hierarchical culture apparatus, a hierarchical culture apparatus group and a culture tower according to the present invention.

The invention content is as follows:

the invention mainly aims to provide a hierarchical culture device, which comprises: a pond farm is separated the module with N, N is separated the module and is in divide N +1 cultivation district in the pond farm. According to the design of the invention, the separation module can change the space of the culture areas by moving forwards and backwards, so that the N +1 culture areas have different space sizes. Therefore, when the stratified culture apparatus of the present invention is used, stratified (Class division) culture can be realized in accordance with the staged volume growth of the aquatic animals to be raised in captivity. Meanwhile, the invention makes an effective hierarchical partition in an accommodating space of the pool farm, so that the utilization rate of the whole accommodating space of the pool farm can be optimally configured.

To achieve the above object, the present invention provides an embodiment of the hierarchical cultivation apparatus, which includes:

a pool farm including a first sidewall and a second sidewall opposite to each other, and a third sidewall and a fourth sidewall opposite to each other;

n binders, connected to the first sidewall and the second sidewall, wherein N is a positive integer, and the binders can move back and forth along the first sidewall and/or the second sidewall to adjust the position thereof;

the N separation modules are combined with the N combined parts of the first side wall and the N combined parts of the second side wall and arranged in the pool farm, so that N +1 cultivation areas are separated in the pool farm;

the separation module comprises L first separation units and K second separation units, one second separation unit is inserted between any two first separation units, and L and K are positive integers;

wherein the total number of the first partition unit and the second partition unit included in the j +1 th partition module is greater than the total number of the first partition unit and the second partition unit included in the j th partition module, and j ∈ N.

In one embodiment, the separation module can be moved back and forth to change the space of the culture area.

In an embodiment, wherein the pool 11 is an artificial pool or a natural pool.

In one embodiment, the space of the j +1 th cultivation area is larger than that of the j th cultivation area.

In an embodiment, wherein the first separating unit comprises:

a first partition plate;

at least one first pivot piece connected to one side of the first partition plate; and

at least one second pivot piece is connected to the other side edge of the first separation plate.

In an embodiment, wherein the second partition unit includes:

a second partition plate;

at least one third pivot piece connected to one side of the second partition plate; and

at least one fourth pivot piece connected to the other side of the second partition plate;

the third pivoting piece and the first pivoting piece or the second pivoting piece are pivoted with each other, so that the second separating unit can be connected with one first separating unit in a chain manner;

the fourth pivoting piece and the first pivoting piece or the second pivoting piece are pivoted with each other, so that the second separating unit is connected with the other first separating unit in a chain manner.

In one embodiment, the second partition plate and the first partition plate are formed with a plurality of passage holes.

In a practical embodiment, the plurality of passage holes included in the second partition plate and the first partition plate of the j +1 th partition module are smaller than the plurality of passage holes included in the second partition plate and the first partition plate of the j th partition module.

In another possible embodiment, the plurality of passage holes included in the second partition plate and the first partition plate of the jth partition module are smaller than the plurality of passage holes included in the second partition plate and the first partition plate of the j +1 th partition module.

The invention also provides a group of pyramid cultivation devices, which comprises Q pyramid cultivation devices as described above, wherein the Q pyramid cultivation devices are adjacent to each other, and Q is a positive integer.

Further, the invention also provides a culture tower, which comprises a plurality of hierarchical culture device groups stacked on one another, wherein the hierarchical culture device groups comprise Q hierarchical culture devices according to the invention, the Q hierarchical culture devices are adjacent to one another, and Q is a positive integer.

In one embodiment, the hierarchical group of culture devices has a two-dimensional figure, and the two-dimensional figure is any one selected from the group consisting of a circle, a triangle, a quadrilateral, a pentagon, a hexagon, a heptagon, an octagon, a nonagon, and a decagon.

Description of the drawings:

fig. 1 is a perspective view of a known artificial pond;

FIG. 2 is a first perspective view of a pyramid cultivation apparatus according to the present invention;

FIG. 3 is a second perspective view of the pyramid-type cultivation apparatus of the present invention;

FIG. 4 is an exploded perspective view of the 1 st partition module shown in FIG. 3;

FIG. 5 is a perspective view of the 1 st partition module shown in FIG. 3;

FIG. 6 is a perspective view of a group of layered cultivation devices according to the present invention; and

fig. 7 is a perspective view of a culture tower of the present invention.

Reference numerals:

1a artificial pond farm

11a first culture area

12a second culture area

1: hierarchical breeding device group

1L hierarchical breeding device

11 pool farm

1W1 first side wall

1W2 second side wall

12: separation module

121: first separation unit

12P1 first divider plate

12S1 first pivot member

12S2 second pivoting member

122 second partition unit

12P2 second partition board

12S3 third pivoting member

12S4 fourth pivoting member

12V channel hole

13: a joint member

2, cultivating tower

The specific implementation mode is as follows:

in order to more clearly describe the hierarchical cultivation device and the cultivation tower of the present invention, the following description will be made in detail with reference to the accompanying drawings.

Fig. 2 and 3 are first and second perspective views of a hierarchical culture device according to the present invention. As shown in fig. 2 and 3, the hierarchical culture apparatus 1L of the present invention mainly includes: a pool farm 11, N binders 13 and N partition modules 12, N is a positive integer. Further, fig. 4 is an exploded perspective view of the 1 st partition module 12 shown in fig. 3. According to the design of the present invention, the pool 11 is an artificial pool or a natural pool, and includes a first side wall 1W1 and a second side wall 1W2 opposite to each other, and a third side wall and a fourth side wall opposite to each other.

In more detail, the first side wall 1W1 and the second side wall 1W2 are both provided with N engaging members 13, and the positions of the engaging members 13 can be movably adjusted. In other words, the coupling member 13 can move back and forth along the first side wall 1W1 and/or the second side wall 1W2 to change and adjust the position thereof. On the other hand, the N partition modules 12 are combined with the N coupling members 13 of the first side wall 1W1 and the N coupling members 13 of the second side wall 1W2 and installed in the pond 11, so as to partition N +1 cultivation areas in the pond 11. For example, fig. 2 exemplarily shows that four of the partitioning modules 12 partition five cultivation areas within the pool farm 11.

As shown in fig. 2, 3 and 4, the separation module 12 includes L first separation units 121 and K second separation units 122, one second separation unit 122 is inserted between any two first separation units 121, and L and K are positive integers. In one embodiment, the first separating unit 121 includes: a first partition 12P1, at least one first pivot 12S1 and at least one second pivot 12S2, wherein the first pivot 12S1 is connected to one side of the first partition 12P1, and the second pivot 12S2 is connected to the other side of the first partition 12P 1. On the other hand, the second partition unit 122 includes: a second partition plate 12P2, at least one third pivot piece 12S3 and at least one fourth pivot piece 12S4, wherein the third pivot piece 12S3 is connected to one side of the second partition plate 12P2, and the fourth pivot piece 12S4 is connected to the other side of the second partition plate 12P 2. According to this design, the third pivot member 12S3 and the first pivot member 12S1 or the second pivot member 12S2 are pivoted to each other, so that the second separating unit 122 is linked to one of the first separating units 121. In addition, the fourth pivot piece 12S4 and the first pivot piece 12S1 or the second pivot piece 12S2 are pivoted to each other, so that the second separating unit 122 is linked with the other first separating unit 121.

According to the design of the present invention, the total number of the first separating units 121 and the second separating units 122 included in the j +1 th separating module 12 is greater than the total number of the first separating units 121 and the second separating units 122 included in the j th separating module 12, and j ∈ N. According to the design, the space of the 1 st cultivation area separated by the 1 st and the 2 nd separation modules 12 is smaller than the space of the 2 nd cultivation area separated by the 2 nd and the 3 rd separation modules 12, and so on. In other words, the space of the j +1 th of the culture area is larger than that of the j th of the culture area.

It should be understood that the user can change and adjust the space of the culture area according to the culture requirement. Specifically, the position of at least one of the connectors 13 on the first side wall 1W1 and/or the second side wall 1W2 is moved back and forth, so that at least one of the partition modules 12 is moved back and forth to change the space of the cultivation area. Thus, large-volume aquatic animals can be housed in a large-space housing area, while small-space housing areas are used for housing small-volume aquatic animals. Therefore, when the stratified culture apparatus 1L of the present invention is used, the aquatic animals can be cultured in a stratified manner (Class division) according to the staged volume growth of the captive aquatic animals. Meanwhile, the invention makes an effective hierarchical partition in an accommodating space of the pool farm 11, so that the utilization rate of the whole accommodating space of the pool farm 11 can be optimally configured.

Fig. 5 is a perspective view of the 1 st partition module 12 shown in fig. 3. It should be noted that, in a possible embodiment, a plurality of passage holes 12V may be dug in the second partition plate 12P2 and the first partition plate 12P 1; meanwhile, the plurality of passage holes 12V included in the second partition plate 12P2 and the first partition plate 12P1 of the j +1 th partition module 12 are made smaller than the plurality of passage holes 12V included in the second partition plate 12P2 and the first partition plate 12P1 of the j-th partition module 12.

For example, the two-dimensional pattern of the pool farm 11 is a fan shape, and 1 st to 4 th partition modules 12 are provided from the center to the circumference, wherein the plurality of passage holes 12V included in the second partition plate 12P2 and the first partition plate 12P1 of the 2 nd partition module 12 are smaller than the plurality of passage holes 12V included in the second partition plate 12P2 and the first partition plate 12P1 of the 1 st partition module 12, and the plurality of passage holes 12V included in the second partition plate 12P2 and the first partition plate 12P1 of the 3 rd partition module 12 are smaller than the plurality of passage holes 12V included in the second partition plate 12P2 and the first partition plate 12P1 of the 2 nd partition module 12, and so on. According to the design, the 1 st to 5 th cultivation areas all have different space sizes. Therefore, aquatic animals (e.g., young seedlings) having a small volume can be housed in the innermost (i.e., 1 st) cultivation area.

Then, after the aquatic animals grow to reach the preset stage 1, the aquatic animals with the growth reached to the stage 1 can be pushed away by moving the separation module 12, so that the aquatic animals enter the 2 nd cultivation area through the plurality of channel holes 12V, and the aquatic animals are changed to be confined in the 2 nd cultivation area. Since the separation module 12 is disposed between the 1 st and the 2 nd cultivation areas, aquatic animals which do not grow to the 1 st stage can swim back to the 1 st cultivation area through the plurality of passage holes 12V, and so on.

In this way, when the stratified culture apparatus 1L of the present invention is used, the aquatic animals can be cultured in a stratified manner (Class division) according to the staged volume growth of the captive aquatic animals. Meanwhile, the invention makes an effective hierarchical partition in an accommodating space of the pool farm 11, so that the utilization rate of the whole accommodating space of the pool farm 11 can be optimally configured. Furthermore, a catching place can be arranged on the circumference of the fan shape. When the aquatic animals confined in the cultivation area of the outermost circle (i.e. the 5 th) grow to a fishing stage, the operator can carry out fishing operation, packaging operation and distribution operation in the fishing place at one go according to the cultivation time sequence.

Of course, in a possible embodiment, it is also designed that the plurality of passage holes 12V included in the second partition plate 12P2 and the first partition plate 12P1 of the j-th partition module 12 are smaller than the plurality of passage holes 12V included in the second partition plate 12P2 and the first partition plate 12P1 of the j + 1-th partition module 12. In this case, it is possible to house aquatic animals (e.g., seedlings) having a small volume in the outermost cultivation area (i.e., the 5 th cultivation area). Then, when the growth reaches the preset 1 st stage, the breeding area can be changed to 4 th breeding area. Because the separation module 12 is arranged between the 4 th culture area and the 5 th culture area, aquatic animals which do not grow to the 1 st stage can swim back to the 5 th culture area through the plurality of channel holes 12V, and so on. Furthermore, a catching place can be arranged at the circle center of the fan shape. When the aquatic animals confined in the innermost (i.e., the 1 st) cultivation area grow to a fishing stage, the operator can perform fishing operation, packaging operation and distribution operation in the fishing place at one go according to the cultivation time sequence.

A group of layered cultivation devices comprising a plurality of layered cultivation devices 1L adjacent to each other

Please refer to fig. 6, which shows a perspective view of a hierarchical cultivation device group according to the present invention. As shown in fig. 6, a plurality of the hierarchical culture devices 1L shown in fig. 1 are adjacent to each other, and then a hierarchical culture device group 1 of the present invention is obtained. As shown in fig. 1 and fig. 6, the hierarchical culture device group 1 is formed by splicing 4 hierarchical culture devices 1L, that is, the hierarchical culture device group 1 has a two-dimensional figure, and the two-dimensional figure is a circle. In this case, N +1 is 5, and each of the pyramid farming apparatuses 1L has five farming areas. In other words, the hierarchical culture apparatus group 1 has a total of 5 × 4-20 culture areas. It is easy to deduce that the two-dimensional pattern of the plant cultivation layer 1L may be a triangle, a quadrangle, a pentagon, a hexagon, a heptagon, an octagon, a nonagon, a decagon, or the like. For example, the triangular pyramid-shaped pyramid-shaped pyramid-shaped-. It should be understood that, in the case that the two-dimensional graph is a circle, the number of the culture areas can be flexibly changed according to the requirement of practical application.

A cultivation tower formed by stacking a plurality of hierarchical cultivation device groups 1

Please refer to fig. 7, which shows a perspective view of a cultivation tower of the present invention. As shown in fig. 7, a plurality of the hierarchical culture device groups 1 shown in fig. 6 are stacked to obtain a culture tower 2 of the present invention.

Thus, the above description is provided for the complete and clear description of the present invention. It should be emphasized, however, that the above detailed description is specific to possible embodiments of the invention, but the embodiments are not intended to limit the scope of the claims, and all equivalent implementations or modifications that do not depart from the technical spirit of the invention are intended to be included within the scope of the claims.

Claims (10)

1. A hierarchical farming device, comprising:

a pool farm including a first sidewall and a second sidewall opposite to each other, and a third sidewall and a fourth sidewall opposite to each other;

n binders, connected to the first sidewall and the second sidewall, wherein N is a positive integer, and the binders can move back and forth along the first sidewall and/or the second sidewall to adjust the position thereof; and

the N separation modules are combined with the N combined parts of the first side wall and the N combined parts of the second side wall and arranged in the pool farm, so that N +1 cultivation areas are separated in the pool farm;

the separation module comprises L first separation units and K second separation units, one second separation unit is inserted between any two first separation units, and L and K are positive integers;

wherein the total number of the first partition unit and the second partition unit included in the j +1 th partition module is greater than the total number of the first partition unit and the second partition unit included in the j th partition module, and j ∈ N.

2. A pyramid-type culture device as claimed in claim 1, wherein the partition module is movable back and forth to change the space of the culture region.

3. A pyramid culturing device according to claim 1, wherein the space of the j +1 th culturing area is larger than that of the j' th culturing area.

4. A pyramid culturing device according to claim 1, wherein the first partitioning unit comprises:

a first partition plate;

at least one first pivot piece connected to one side of the first partition plate; and

at least one second pivot piece is connected to the other side edge of the first separation plate.

5. A pyramid culturing device according to claim 4, wherein the second partition unit comprises:

a second partition plate;

at least one third pivot piece connected to one side of the second partition plate; and

at least one fourth pivot piece connected to the other side of the second partition plate;

the third pivoting piece and the first pivoting piece or the second pivoting piece are pivoted with each other, so that the second separating unit can be connected with one first separating unit in a chain manner;

the fourth pivoting piece and the first pivoting piece or the second pivoting piece are pivoted with each other, so that the second separating unit is connected with the other first separating unit in a chain manner.

6. The stepped aquaculture apparatus of claim 5 wherein the second partition plate and the first partition plate are each formed with a plurality of passage holes.

7. The pyramid culturing device of claim 6, wherein the plurality of passage holes included in the second and first partition plates of the j +1 th partition module are smaller than the plurality of passage holes included in the second and first partition plates of the j th partition module.

8. The pyramid culturing device of claim 6, wherein the plurality of passage holes included in the second and first partitions of the j-th module are smaller than the plurality of passage holes included in the second and first partitions of the j + 1-th module.

9. A group of pyramid cultivation devices, comprising Q pyramid cultivation devices as claimed in any one of claims 1 to 8, wherein the Q pyramid cultivation devices are adjacent to each other and Q is a positive integer.

10. A cultivation tower comprising a plurality of hierarchical cultivation device groups stacked on top of each other, wherein the hierarchical cultivation device group comprises Q hierarchical cultivation devices according to any one of claims 1 to 8, the Q hierarchical cultivation devices are adjacent to each other, and Q is a positive integer.

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