CN111149756A

CN111149756A - Penaeus monodon test device

Info

Publication number: CN111149756A
Application number: CN202010004012.7A
Authority: CN
Inventors: 姜松; 周发林; 江世贵; 杨其彬; 黄建华; 杨丽诗; 莫贤斌
Original assignee: Shenzhen Test Base South China Sea Fisheries Research Institute Chinese Academy Of Fishery Sciences; South China Sea Fisheries Research Institute Chinese Academy Fishery Sciences
Current assignee: Shenzhen Test Base South China Sea Fisheries Research Institute Chinese Academy Of Fishery Sciences; South China Sea Fisheries Research Institute Chinese Academy Fishery Sciences
Priority date: 2020-01-03
Filing date: 2020-01-03
Publication date: 2020-05-15
Anticipated expiration: 2040-01-03
Also published as: CN111149756B

Abstract

The invention discloses a penaeus monodon test device, which comprises: the wall, a plurality of monitoring assemblies embedded in the wall and a test assembly arranged on one side of the wall; the testing assembly comprises a plurality of horizontally placed testing tubes, and the heads and the tails of the adjacent testing tubes are communicated through a tee; the plurality of test tubes are sequentially arranged in layers along the vertical direction, the plurality of test tubes can simulate sea areas with different depths, the bottoms of the test tubes are provided with simulation grooves, and seabed materials are arranged in the simulation grooves; the test assembly comprises a support and a plurality of probes distributed at intervals along the length direction of the support, the probes can move along the length direction of the support, and the test assembly can monitor the penaeus monodon.

Description

Penaeus monodon test device

Technical Field

The invention relates to a test device, in particular to a penaeus monodon test device.

Background

Penaeus monodon is commonly known as Coprinus comatus, prawns, Oppenaeus japonicus, Pandalus japonicus, Penaeus amansii, Penaeus monodon and Penaeus nivorus, and is commonly known as giant tiger shrimp by food and agriculture organization of the United nations, the parent of the Penaeus monodon is from African wild Penaeus monodon, and the Penaeus is the largest species in the genera Penaeus in taxonomic membership to arthropoda, Panonychus, Panonychidae, Branchirophaga, Penaeus. The penaeus monodon is wide in salt property, resistant to high temperature and low oxygen, weak in adaptability to low temperature and strong in disease resistance, penaeus monodon is fond of inhabiting in sand mud or sediment, generally remains still in the daytime and has the strongest appetite in the evening, and starts to frequently seek food activities. The salinity adaptation range of the organic fertilizer is 5-25, and the growth is faster as the salinity adaptation range is closer to 10. The suitable temperature range is 14-34 ℃, the optimum growth water temperature is 25-30 ℃, the food intake is stopped when the water temperature is lower than 18 ℃, and the food cannot die as long as the water temperature is not lower than 12 ℃. The bait has strong omnivorous property, the requirement on feed protein is 35-40%, shellfish, trash fish, shrimp, peanut bran, wheat bran and the like can be ingested, the optimum growth environment of the penaeus monodon can be analyzed by analyzing the behavior of the penaeus monodon, and the penaeus monodon can be better cultured.

Traditional penaeus monodon's test device only can test penaeus monodon single element's action reaction, can't detect penaeus monodon in many-sided integrated test such as vision, light source, growing environment and temperature, and test effect is comparatively single, can't carry out omnidirectional test, and traditional test device occupation space is great, and the monitoring subassembly is not inlayed in the wall, and can't simulate out the water environment of the different degree of depth sea areas, and the practicality is not strong.

Disclosure of Invention

The invention overcomes the defects of the prior art and provides a penaeus monodon test device.

In order to achieve the purpose, the invention adopts the technical scheme that: a penaeus monodon test device, comprising: the wall, a plurality of monitoring assemblies embedded in the wall and a test assembly arranged on one side of the wall; the testing assembly comprises a plurality of horizontally placed testing tubes, and the heads and the tails of the adjacent testing tubes are communicated through a tee; the plurality of test tubes are sequentially arranged in layers along the vertical direction, the plurality of test tubes can simulate sea areas with different depths, the bottoms of the test tubes are provided with simulation grooves, and seabed materials are arranged in the simulation grooves; the test assembly comprises a support and a plurality of probes distributed at intervals along the length direction of the support, the probes can move along the length direction of the support, and the test assembly can monitor the penaeus monodon.

In a preferred embodiment of the invention, the probe can be used for acquiring images of the penaeus monodon in real time, and the angle of the probe can be adjusted.

In a preferred embodiment of the present invention, any two probes are in a group, and the group of probes forms a left view and a right view through different viewpoints to be respectively displayed to the left eye and the right eye, so as to form a stereoscopic image.

In a preferred embodiment of the present invention, at least one nozzle is disposed on any one of the test tubes, the nozzle can adjust the water temperature in the test tube, and the water temperature in the test tube gradually increases from top to bottom.

In a preferred embodiment of the invention, the seabed material can be a composition of seabed material of different sea areas.

In a preferred embodiment of the present invention, a groove is formed at a position corresponding to the test tube on one side of the wall, and the bracket is disposed in the groove.

In a preferred embodiment of the present invention, a one-way light-transmitting plate is inserted into one end of the groove, and the one-way light-transmitting plate can shield the monitoring assembly.

In a preferred embodiment of the present invention, the one-way light-transmitting plate can move along the length direction of the groove.

In a preferred embodiment of the present invention, a unidirectional light-transmitting layer is disposed on the outer wall of the test tube.

In a preferred embodiment of the present invention, a feeding member is disposed at one end of the simulation slot.

In a preferred embodiment of the invention, the feeding element comprises a spiral plate and a clamping column, the spiral plate can rotate to convey nutrients into the simulation groove, and the clamping column is convenient to hold for rotating the spiral plate.

In a preferred embodiment of the present invention, the spiral plate rotates clockwise, and the spiral directions of the spiral plate are distributed counterclockwise.

In a preferred embodiment of the present invention, there is parallax between the left and right views formed by a set of probes.

The invention solves the defects in the background technology, and has the following beneficial effects:

(1) through the test tube along vertical direction layering, the different water pressures of formation in every layer of test tube, simulate out the penaeus monodon living environment of different degree of depth sea areas through hydraulic difference to the growth state of monitoring penaeus monodon provides the powerful foundation for the breed of penaeus monodon.

(2) The adjacent test tubes are communicated end to end through a tee joint, and when the living environment of the penaeus monodon in the current test tube feels uncomfortable or oppressed, the penaeus monodon can escape and migrate to other test tubes, so that the optimal culture environment of the penaeus monodon is judged.

(3) The spiral plate is the clockwise rotation, the spiral direction of spiral plate distributes for anticlockwise, and when every rotation was attacked a spiral plate station, the homoenergetic was carried the nourishment to the simulation inslot through the while in the sealed simulation groove of spiral plate, can not make the seabed material or the water of simulation inslot run off from throwing edible part position.

(4) The simulation groove sets up in test tube bottom, and the top terminal surface and the test tube inner wall in simulation groove flush, can not cause the intraductal seabed matter of upper test to flow into the test of lower floor intraductally, cause the mixture of seabed matter, influence experimental effect.

(5) The water temperature in the test tubes is adjusted through the spray heads, so that the temperatures in different test tubes are distributed in a gradient manner, and the water temperature for the optimal growth of the penaeus monodon can be tested.

Drawings

FIG. 1 is a schematic partial structure view of a preferred embodiment of the present invention;

FIG. 2 is a schematic structural view of a monitoring assembly of the preferred embodiment of the present invention;

reference numerals:

1. wall, 2, tee bend, 3, simulation groove, 4, test tube, 5, throw edible piece, 6, one-way light-passing board, 7, handle, 8, support, 9, probe, 10, recess.

Detailed Description

The invention will now be described in further detail with reference to the accompanying drawings and examples, which are simplified schematic drawings and illustrate only the basic structure of the invention in a schematic manner, and thus show only the constituents relevant to the invention.

As shown in fig. 1-2, a penaeus monodon test device comprises: the wall 1, a plurality of monitoring assemblies embedded in the wall 1 and a test assembly arranged on one side of the wall 1; the testing assembly comprises a plurality of horizontally placed testing tubes 4, and the heads and the tails of the adjacent testing tubes 4 are communicated through a tee joint 2; the plurality of test tubes 4 are sequentially arranged in layers along the vertical direction, the plurality of test tubes 4 can simulate sea areas with different depths, the bottom of each test tube 4 is provided with a simulation groove 3, and seabed materials are arranged in the simulation grooves 3; the test assembly comprises a support 8 and a plurality of probes 9 distributed at intervals along the length direction of the support 8, the probes 9 can move along the length direction of the support 8, the test assembly can monitor the penaeus monodon, the probes 9 can acquire images of the penaeus monodon a real-time basis, and the probes 9 can adjust angles.

Through test tube 4 along vertical direction layering distribution, form different water pressures in every layer of test tube 4, simulate out the penaeus monodon living environment of different degree of depth sea areas through hydraulic difference to the growth state of monitoring penaeus monodon provides the powerful foundation for the breed of penaeus monodon.

The adjacent test tubes 4 are communicated end to end through the tee joint 2, and when the living environment of the penaeus monodon in the current test tube 4 feels uncomfortable or oppressed, the penaeus monodon can escape and migrate to other test tubes 4, so that the best culture environment of the penaeus monodon is judged.

Any two probes 9 form a group, a left view and a right view formed by the group of probes 9 through different viewpoints are respectively displayed to the left eye and the right eye to form a stereoscopic image, and parallax exists between the left view and the right view formed by the group of probes 9.

It is arbitrary be provided with at least one shower nozzle on the test tube 4, the position that the shower nozzle set up can be on the tee bend 2 at test tube 4 both ends, also can set up at test tube 4 pipe shaft, as long as can all can in the test tube 4 that corresponds is gone into to the water injection in the shower nozzle, the shower nozzle can be adjusted the temperature in the test tube 4, the temperature in the test tube 4 increases gradually from last to bottom, through the temperature in the shower nozzle adjustment test tube 4, but the temperature in the different test tubes 4 is the gradient and distributes, can test the temperature of the best growth of penaeus monodon.

The simulation groove 3 is arranged at the bottom of the test tube 4, the top end face of the simulation groove 3 is flush with the inner wall of the test tube 4, seabed substances in the upper test tube 4 cannot flow into the lower test tube 4, seabed substances are mixed, the test effect is influenced, the seabed substances can be seabed substance components in different sea areas, a groove 10 is formed in the position, corresponding to the test tube 4, on one side of the wall 1, the support 8 is arranged in the groove 10, one end of the groove 10 is provided with the one-way light-transmitting plate 6 in an inserting mode, one end of the one-way light-transmitting plate 6 is provided with a handle 7, and the size of the area, where the one-way light-transmitting plate 6 shields the groove 10, and the number of the shielding probes 9; one-way light-passing board 6 can shelter from the monitoring subassembly, one-way light-passing board 6 can move along recess 10 length direction, moves one-way light-passing board 6 and can shelter from partial or whole probe 9, and probe 9 can continue to survey the penaeus monodon-site in the test tube 4, and the penaeus monodon in the test tube 4 can not see probe 9 yet, can not cause the startle of penaeus monodon.

In another embodiment of the present invention, a light source lamp may also be disposed in the groove 10, and the unidirectional light-transmitting plate 6 shields part or all of the light source, so as to create different brightness for the local position or all of the positions of the testing tube 4, thereby performing a contrast analysis.

The outer wall of the test tube 4 is provided with a one-way euphotic layer which can prevent the penaeus monodon from seeing the external environment or moving artificially, the action of the penaeus monodon can not be influenced by the movement of a tester, one end of the simulation groove 3 is provided with a feeding piece 5, the feeding piece 5 comprises a spiral plate and a clamping column, the spiral plate can rotate to convey nutrients into the simulation groove 3, the clamping column is convenient to hold to rotate the spiral plate, the spiral plate rotates clockwise, the spiral direction of the spiral plate is distributed anticlockwise, the spiral plate rotates clockwise, the spiral direction of the spiral plate is distributed in the anticlockwise direction, when one spiral plate station is tapped in a rotating way, the simulated tank 3 is sealed through the spiral plate, meanwhile, nutrients are conveyed into the simulated tank 3, and therefore seabed materials or water in the simulated tank 3 cannot run off from the part of the feeding piece 5.

In light of the foregoing description of the preferred embodiment of the present invention, it is to be understood that various changes and modifications may be made by one skilled in the art without departing from the spirit and scope of the invention. The technical scope of the present invention is not limited to the content of the specification, and must be determined according to the scope of the claims.

Claims

1. A penaeus monodon test device, comprising: the wall, a plurality of monitoring assemblies embedded in the wall and a test assembly arranged on one side of the wall; it is characterized in that the preparation method is characterized in that,

the testing assembly comprises a plurality of horizontally placed testing tubes, and the heads and the tails of the adjacent testing tubes are communicated through a tee;

the plurality of test tubes are sequentially arranged in layers along the vertical direction, the plurality of test tubes can simulate sea areas with different depths, the bottoms of the test tubes are provided with simulation grooves, and seabed materials are arranged in the simulation grooves;

the test assembly comprises a support and a plurality of probes distributed at intervals along the length direction of the support, the probes can move along the length direction of the support, and the test assembly can monitor the penaeus monodon.

2. The penaeus monodon test device according to claim 1, characterized in that: the probe can be used for acquiring images of the penaeus monodon in real time, and the angle of the probe can be adjusted.

3. The penaeus monodon test device according to claim 2, characterized in that: any two probes form a group, and the group of probes form a left view and a right view through different viewpoints to be respectively displayed to the left eye and the right eye to form a three-dimensional image.

4. The penaeus monodon test device according to claim 1, characterized in that: and at least one sprayer is arranged on any test tube, and the water temperature in the test tube can be adjusted by the sprayer.

5. The penaeus monodon test device according to claim 1, characterized in that: the seafloor material can be a composition of seafloor material of different sea areas.

6. The penaeus monodon test device according to claim 1, characterized in that: the wall one side with the position that the test tube corresponds is provided with the recess, the support sets up in the recess.

7. The penaeus monodon test device according to claim 6, characterized in that: one end of the groove is provided with a one-way light-transmitting plate in a penetrating mode, and the one-way light-transmitting plate can shield the monitoring assembly.

8. The penaeus monodon test device according to claim 7, characterized in that: the one-way light-transmitting plate can move along the length direction of the groove.

9. The penaeus monodon test device according to claim 1, characterized in that: and a one-way euphotic layer is arranged on the outer wall of the test tube.

10. The penaeus monodon test device according to claim 1, characterized in that: and a feeding piece is arranged at one end of the simulation groove.