CN220211524U - Intelligent fish ring barrel culture system for laboratory - Google Patents

Abstract

The utility model discloses an intelligent fish ring barrel culture system for a laboratory, which is characterized in that: the utility model provides a breed system including breeding the bucket, the bottom surface of breeding the bucket is the inclined plane, is connected with and breeds the bucket drain pipe in the bucket bottom, breed the bucket drain pipe and breed the junction of bucket and be located the relatively lower one end of inclined plane, breed bucket drain pipe on has set gradually manual drain pipe, Y type filter and solenoid valve, be provided with first manual valve on the manual drain pipe, the solenoid valve then links to each other with the remote controller of distal end through remote control relay, breed system still includes the water tank, be connected with the return line that has the water pump on the water tank, the exit end of return line is located the top of breeding the bucket, and still be provided with the manual valve of second in the exit end department of return line, breed system still include the air pump, the exit of air pump is connected with the gas circuit, the end of gas circuit is provided with the gas stone, the gas stone is arranged in breeding the bucket.

Description

Intelligent fish ring barrel culture system for laboratory

Technical Field

The utility model relates to the field of aquaculture, in particular to an intelligent fish ring barrel aquaculture system for a laboratory.

Background

When the fish culture bait is researched, a culture test is needed, namely, the prepared culture bait is used for culturing target fish, and the growth condition of the target fish is observed in the culture process so as to determine the effect of the culture bait.

In the cultivation process, a part of bait residues are always reserved in a cultivation container, meanwhile, feces generated in the fish growth process can be mixed with the bait residues to form solid impurities in the cultivation process, and the relevant parameters of the solid impurities, such as loosening degree after the bait is soaked for a certain time, nutrient component residues in the feces and the like, are analyzed, so that the method has very important reference significance for the configuration of cultivation baits.

In the traditional cultivation test, most cultivation equipment is relatively crude, diseases or death of cultivated fishes are easy to cause, the final experimental result is affected once the problems occur, and meanwhile, the traditional equipment is inconvenient to collect solid impurities effectively.

There is thus a need for a method or apparatus that solves the above-mentioned problems.

Disclosure of Invention

The intelligent fish ring barrel culture system is simple in structure, ingenious in design and reasonable in layout, can effectively control water quality, ensures normal and healthy survival of experimental fish, and can conveniently and rapidly collect solid impurities.

The technical scheme of the utility model is as follows: a intelligent fish circle bucket farming systems for laboratory, its characterized in that: the cultivation system comprises a cultivation barrel 1, the bottom surface of the cultivation barrel 1 is an inclined surface 2, the bottom of the cultivation barrel 1 is connected with a cultivation barrel drainage pipeline 3, the joint of the cultivation barrel drainage pipeline 3 and the cultivation barrel 1 is positioned at one relatively lower end of the inclined surface 2, the cultivation barrel drainage pipeline 3 is sequentially provided with a manual drainage pipeline 4, a Y-shaped filter 5 and an electromagnetic valve 6, the manual drainage pipeline 4 is provided with a first manual valve 7, the electromagnetic valve 6 is connected with a remote controller 9 at the far end through a remote control relay 8,

the cultivation system also comprises a water tank 11, the water tank 11 is connected with a water return pipeline 13 with a water pump 12, the outlet end of the water return pipeline 13 is positioned above the cultivation barrel 1, a second manual valve 14 is also arranged at the outlet end of the water return pipeline 13,

the cultivation system further comprises an air pump 15, an air channel 16 is connected to the outlet end of the air pump 15, an air stone 17 is arranged at the tail end of the air channel 16, and the air stone 17 is arranged in the cultivation barrel 1.

The cultivation system comprises a plurality of cultivation barrels 1, and the cultivation barrels 1 are respectively connected with a wastewater discharge pipeline 10 in parallel through cultivation barrel drainage pipelines 3 connected with the cultivation barrels.

The water tank 11 comprises a plurality of independent small water tanks 18.

Compared with the prior art, the utility model has the following advantages:

the intelligent fish ring barrel culturing system for the laboratory is simple in structure, ingenious in design and reasonable in layout, aims at various problems existing in the conventional fish culturing process in the laboratory, designs a special structure, designs the barrel bottom of the culturing barrel into an inclined plane so as to facilitate collection and discharge of solid impurities such as excrement and bait residues, and is provided with a draining pipeline with a manual valve, a Y-shaped filter and an electromagnetic valve on a discharging pipeline, wherein the electromagnetic valve can be remotely controlled, so that the workload of operators is reduced, and meanwhile, the Y-shaped filter can collect the solid impurities in a water body in the draining process, so that convenience is provided for subsequent bait analyzing work, the manufacturing process is simple, the manufacturing cost is low, and the intelligent fish ring barrel culturing system is particularly suitable for popularization and application in the field and has a wide market prospect.

Drawings

FIG. 1 is a schematic representation of the results of an embodiment of the present utility model.

Detailed Description

Specific embodiments of the present utility model will be described below with reference to the accompanying drawings. As shown in fig. 1: the intelligent fish ring barrel cultivation system for the laboratory comprises a cultivation barrel 1, wherein the bottom surface of the cultivation barrel 1 is an inclined surface 2, the bottom of the cultivation barrel 1 is connected with a cultivation barrel drainage pipeline 3, the joint of the cultivation barrel drainage pipeline 3 and the cultivation barrel 1 is positioned at one relatively lower end of the inclined surface 2, a manual drainage pipeline 4, a Y-shaped filter 5 and an electromagnetic valve 6 are sequentially arranged on the cultivation barrel drainage pipeline 3, a first manual valve 7 is arranged on the manual drainage pipeline 4, the electromagnetic valve 6 is connected with a remote controller 9 at the far end through a remote control relay 8,

the cultivation system also comprises a water tank 11, the water tank 11 is connected with a water return pipeline 13 with a water pump 12, the outlet end of the water return pipeline 13 is positioned above the cultivation barrel 1, a second manual valve 14 is also arranged at the outlet end of the water return pipeline 13,

the cultivation system further comprises an air pump 15, an air channel 16 is connected to the outlet end of the air pump 15, an air stone 17 is arranged at the tail end of the air channel 16, and the air stone 17 is arranged in the cultivation barrel 1.

In view of cultivation efficiency, the cultivation barrels 1 can be multiple, when the system comprises multiple cultivation barrels 1, each cultivation barrel 1 is connected with a cultivation barrel drainage pipeline 3, all cultivation barrel drainage pipelines 3 are connected in parallel on a drainage pipeline 10,

the water tank 11 comprises a plurality of independent small water tanks 18.

The working process of the intelligent fish ring barrel culture system for the laboratory provided by the embodiment of the utility model is as follows: in the cultivation process, the air pump 15 works, and air is injected into the cultivation barrel 1 through the air stone 17 so as to increase the dissolved oxygen content of the cultivation water body;

the experimental fish is cultivated in the cultivation barrel 1, experimental bait is thrown into the cultivation barrel 1 at regular time and quantity, the feeding condition of the experimental fish is observed, after a certain time of feeding, a part of residual bait exists in the cultivation barrel 1, meanwhile, the experimental fish can produce feces, and the solid impurities are deposited on the relatively lower end of the inclined surface 2 at the bottom end of the cultivation barrel 1,

when the culture water body needs to be replaced or the solid impurities are collected, a command is remotely sent through the remote controller 9, the remote control relay 8 triggers the electromagnetic valve 6 to act after receiving a signal, the electromagnetic valve 6 is opened, the water body in the culture barrel 1 can enter the culture barrel drainage pipeline 3 together with the solid impurities, the solid impurities in the water body can be intercepted by the Y-shaped filter 5, and the water body filtered by the Y-shaped filter 5 can be directly discharged into a drainage system through the drainage pipeline 10;

after a period of time, an operator can detach the filter element in the Y-shaped filter 5, replace a new filter element, take out solid impurities in the replaced filter element, and then carry out subsequent analysis operation;

if the electromagnetic valve 6 fails or fails, the first manual valve 7 arranged on the manual drainage pipeline 4 can be directly opened to realize manual drainage of wastewater,

the water tank 11 comprises a plurality of mutually independent small water tanks 18, the small water tanks 18 which are not connected with the water return pipeline 13 at present are used for trapping water, and the small water tanks 18 which are kept stand for a certain time (trapped water) can be connected with the water return pipeline 13 to supplement fresh water for the cultivation barrel 1.

Claims (3)

1. A intelligent fish circle bucket farming systems for laboratory, its characterized in that: the cultivation system comprises a cultivation barrel (1), the bottom surface of the cultivation barrel (1) is an inclined surface (2), a cultivation barrel drainage pipeline (3) is connected to the bottom of the cultivation barrel (1), the joint of the cultivation barrel drainage pipeline (3) and the cultivation barrel (1) is located at one relatively lower end of the inclined surface (2), a manual drainage pipeline (4), a Y-shaped filter (5) and an electromagnetic valve (6) are sequentially arranged on the cultivation barrel drainage pipeline (3), a first manual valve (7) is arranged on the manual drainage pipeline (4), the electromagnetic valve (6) is connected with a remote controller (9) at the far end through a remote control relay (8),

the cultivation system also comprises a water tank (11), the water tank (11) is connected with a water return pipeline (13) with a water pump (12), the outlet end of the water return pipeline (13) is positioned above the cultivation barrel (1), a second manual valve (14) is also arranged at the outlet end of the water return pipeline (13),

the cultivation system also comprises an air pump (15), an air passage (16) is connected to the outlet end of the air pump (15), an air stone (17) is arranged at the tail end of the air passage (16), and the air stone (17) is arranged in the cultivation barrel (1).

2. The intelligent fish tank farming system for laboratories according to claim 1, wherein: the cultivation system comprises a plurality of cultivation barrels (1), and the cultivation barrels (1) are respectively connected with a wastewater discharge pipeline (10) in parallel through cultivation barrel drainage pipelines (3) connected with the cultivation barrels.

3. The intelligent fish tank farming system for laboratories according to claim 1, wherein: the water tank (11) comprises a plurality of independent small water tanks (18).