CN213427820U - Intelligent aquatic animal breeding system for laboratory - Google Patents

Abstract

An intelligent aquatic animal culture system for a laboratory. The utility model relates to an aquatic animals culture system. The utility model discloses a solve current laboratory shui nationality breed in-process, the accurate nature and the repeatability of experiment are difficult to guarantee, lead to the experimental result to receive the problem of influence. The utility model discloses a laboratory is bred the fish bowl, lighting mechanism, automatic feeding is eaten the mechanism, level sensor, oxygenation mechanism, dissolved oxygen detection module, many detection module, illumination sensor, filter circulation mechanism and controller, lighting mechanism sets up the upper end of breeding the fish bowl in the laboratory, automatic feeding is eaten the one side that the mechanism set up the fish bowl upper end was bred in the laboratory, level sensor sets up on the lateral wall in the fish bowl is bred in the laboratory, oxygenation mechanism, dissolved oxygen detection module, many detection module and illumination sensor all set up the cylinder bottom of breeding the fish bowl in the laboratory, the fish bowl is bred in the laboratory and is connected with filter circulation mechanism. The utility model is used for laboratory aquatic animals are bred.

Description

Intelligent aquatic animal breeding system for laboratory

Technical Field

The utility model relates to an shui nationality farming systems, concretely relates to laboratory intelligence shui nationality farming systems.

Background

In order to facilitate research on aquatic organisms by researchers, aquatic breeding in laboratories is required to understand the characteristics of the organisms. In the aquatic animal breeding process, in order to ensure that a laboratory controlled experiment is accurately carried out, the laboratory aquatic animal system has strict requirements on the breeding environment and conditions of tested aquatic animals, such as water quality indexes of water temperature, pH value, conductivity, TDS value, dissolved oxygen amount and the like, illumination intensity and period, feeding time, feeding amount and other parameters, so that the accuracy and repeatability of experimental results are ensured, and experimental result errors and even experimental failure are avoided to the maximum extent. At present, the same type of intelligent aquatic animal system suitable for aquatic animal experiments does not exist in the market.

SUMMERY OF THE UTILITY MODEL

The utility model discloses a solve current laboratory shui nationality breeding in-process, the accurate nature and the repeatability of experiment are difficult to guarantee, lead to the experimental result to receive the problem of influence, and then provide a laboratory intelligence shui nationality farming systems.

The utility model discloses a solve the technical scheme that above-mentioned technical problem took and be:

the utility model provides a laboratory intelligence shui nationality farming systems includes the laboratory and breeds the fish bowl, lighting mechanism, automatically, feed and eat the mechanism, level sensor, oxygenation mechanism, dissolved oxygen detection module, many detection module, illumination sensor, filtration cycle mechanism and controller, lighting mechanism sets up the upper end of breeding the fish bowl in the laboratory, automatically, feed and eat the one side that the mechanism set up the fish bowl upper end is bred in the laboratory, level sensor sets up on the lateral wall in the fish bowl is bred in the laboratory, oxygenation mechanism, dissolved oxygen detection module, many detection module and illumination sensor all set up the cylinder bottom of breeding the fish bowl in the laboratory, the fish bowl is bred in the laboratory and is connected with filtration cycle mechanism, lighting mechanism, automatically, feed and eat the mechanism, level sensor, oxygenation mechanism, dissolved oxygen detection module, many detection module, illumination sensor and filtration cycle mechanism all are connected with the controller.

The utility model has the advantages that:

the utility model provides a laboratory intelligence shui nationality farming systems can carry out real-time supervision and regulation to temperature, water level, the dissolved oxygen volume etc. of shui nationality system, can also the automatic control illumination simultaneously and realize regularly quantitative automatic feeding, according to the numerical value of pH valve, conductivity, water hardness detection module feedback, judges whether should carry out filter media washing, change to utilize the branch storehouse blow off pipe in each storehouse to carry out the blowdown operation. The intelligent aquatic animal breeding method has the advantages that the intelligent aquatic animal breeding is realized, the accuracy and the repeatability of the experimental result are ensured, and the experimental result error and even the experimental failure are avoided to the greatest extent.

Drawings

FIG. 1 is a front view of the overall structure of the present invention;

fig. 2 is a top view of fig. 1.

Detailed Description

The first embodiment is as follows: with reference to fig. 1 to 2, the laboratory intelligent aquarium culture system according to this embodiment includes a laboratory culture aquarium 1, an illumination mechanism 111, an automatic feeding mechanism 112, a water level sensor 113, an oxygen increasing mechanism 114, a dissolved oxygen detection module 115, a multi-position detection module 116, an illumination sensor 117, a filtering circulation mechanism and a controller, the illumination mechanism 111 is disposed at an upper end of the laboratory culture aquarium 1, the automatic feeding mechanism 112 is disposed at one side of the upper end of the laboratory culture aquarium 1, the water level sensor 113 is disposed on a side wall of the laboratory culture aquarium 1, the oxygen increasing mechanism 114, the dissolved oxygen detection module 115, the multi-position detection module 116 and the illumination sensor 117 are disposed at a bottom of the laboratory culture aquarium 1, the laboratory culture aquarium 1 is connected to the filtering circulation mechanism, the illumination mechanism 111, the automatic feeding mechanism 112, the water level sensor 113, the oxygen increasing mechanism 114, the illumination mechanism 117, The dissolved oxygen detection module 115, the multi-position detection module 116, the illumination sensor 117 and the filtration cycle mechanism are all connected to the controller.

In this embodiment, the corresponding index is monitored by the corresponding monitoring and detecting module, and the signal is fed back to the controller, and the judgment is performed according to the numerical value range preset in different experiments, and the controller can perform corresponding operations such as turning on and off the illuminating mechanism 111, controlling the heating rod in the filtering circulation mechanism to be heated or turned off, controlling the flow of the oxygenation pump of the oxygenation mechanism 114 to be increased or decreased, and the like; and judging whether the filter material should be cleaned and replaced according to the numerical values fed back by the pH, conductivity and TDS monitoring modules, and performing sewage discharge operation by using the bin-dividing sewage discharge pipes of each bin. The automatic feeding function of the experimental animals is carried out at regular time and quantity according to the experimental setting requirements, and the filtering circulation mechanism and the oxygen increasing mechanism 114 are closed during feeding so as to prevent fish food from floating around along with water flow and polluting water quality.

Specifically, the illumination sensor 117 can detect the illumination intensity of the laboratory culture fish tank 1, when the illumination intensity is lower than a preset lowest value, the illumination sensor 117 transmits a control signal to the controller, the controller turns on the illumination mechanism 111 for illumination, when the light value is higher than a preset highest value, the illumination sensor 117 transmits the control signal to the controller, the controller turns off the illumination mechanism 111, and meanwhile, the illumination sensor 117 can regulate and control the illumination brightness of the illumination mechanism 111 in real time through the controller according to the detected immediate light value; the dissolved oxygen detection module 115 can detect the dissolved oxygen amount in the laboratory culture fish tank 1, when the dissolved oxygen amount is lower than a preset lowest value, the dissolved oxygen detection module 115 transmits a control signal to the controller, the controller starts the oxygenation mechanism 114 to inject oxygen into the laboratory culture fish tank 1, when the dissolved oxygen amount is higher than the preset highest value, the dissolved oxygen detection module 115 transmits the control signal to the controller, the controller closes the oxygenation mechanism 114, and meanwhile, the dissolved oxygen detection module 115 can regulate and control the flow of the oxygenation mechanism 114 in real time through the controller according to the detected instant numerical value of the dissolved oxygen amount so as to ensure the dissolved oxygen amount to be constant; the water level sensor 113 can detect the water level in the laboratory culture fish tank 1, when the water level is lower than a preset minimum value, the water level sensor 113 transmits a signal to the controller, and the controller gives an alarm to remind a worker to open the water replenishing valve 83 in time for replenishing water; the automatic feeding mechanism 112 comprises a plurality of feeding bins arranged in parallel, a certain amount of bait is pre-filled in each feeding bin, each feeding bin is provided with an automatic bin gate, the automatic bin gates are connected with the controller, the controller opens one automatic bin gate at certain intervals, the bait in each feeding bin falls into the laboratory culture fish tank 1, and the automatic feeding at regular time and quantity is completed; the multi-position detection module 116 can detect the temperature, the pH value, the total dissolved solid content and the conductivity in the laboratory culture fish tank 1 and transmit a control signal to the controller, the controller controls the electric heating rod 71 to control the received temperature signal, when the detected temperature is lower than a preset minimum value, the controller controls the electric heating rod 71 to start heating, when the detected temperature is higher than a preset maximum value, the controller controls the electric heating rod 71 to close, and meanwhile, according to the instant numerical value of the detected temperature, the controller regulates and controls the heating temperature of the electric heating rod 71 in real time so as to ensure that the laboratory culture fish tank 1 is in a constant temperature state; the controller is to received pH valve, water hardness and conductivity signal, when received signal is higher than predetermineeing the highest value, the controller sends the warning, reminds the staff in time to wash, change the filter media to utilize the branch storehouse blow off pipe in each storehouse to carry out blowdown operation.

Breed fish bowl rivers in laboratory breed fish bowl 1 in the filtration circulation mechanism enter into overflow district 12 after the overflow of baffling board 121 and overflow board 122, enter into precipitation storehouse 2 via downcomer 21 again, overflow enters into dry and wet disengagement zone 3 after deposiing again, enter into physics filter storehouse 4 after dual drip in proper order, chemistry filter storehouse 5 and biological filter storehouse 6, the oxygenation of annotating oxygen through oxygen dish 51 simultaneously, after the heating of heating bin 7 again, get into the clean water storehouse, the fish bowl is taken out along the upper hose to the water purification of will purifying water by the water pump operation, thereby realize purification and cyclic utilization of experiment breed water quality of water.

The utility model discloses well deposit the below that storehouse 2 set up breeding fish bowl 1 in the laboratory, physics is filtered storehouse 4, chemistry and is filtered storehouse 5 and biological filtration storehouse 6 and set up side by side in the lower part that deposits storehouse 2 one side in proper order, and dry and wet disengagement zone 3 sets up on the upper portion of depositing 2 one sides in storehouse and is located physics filtration storehouse 4, chemistry and filters the upper end in storehouse 5 and biological filtration storehouse 6, and clean water storehouse 8 sets up in one side of biological filtration storehouse 6, and heated warehouses 7 sets up between biological filtration storehouse 6 and clean water storehouse 8. The design makes the whole filtration cycle system compact in structure and reduces the occupied space.

The second embodiment is as follows: referring to fig. 1 to 2, the multi-position detection module 116 according to the present embodiment is a four-in-one detection module for temperature, ph, total dissolved solids, and conductivity. Other components and connection modes are the same as those of the first embodiment.

The third concrete implementation mode: with reference to fig. 1 to 2, the filtering circulation mechanism of the present embodiment includes an overflow area 12, a precipitation bin 2, a dry-wet separation area 3, a filtering bin area and a purified water bin 8, the overflow area 12 is disposed in the laboratory culture fish tank 1, a water outlet end at a bottom end of the overflow area 12 is connected to a water inlet end of the precipitation bin 2, water at a water outlet end of the precipitation bin 2 sequentially passes through the dry-wet separation area 3 and the filtering bin area from beginning to end and then enters the purified water bin 8, and a water outlet end of the purified water bin 8 is connected to a water inlet end of the laboratory culture fish tank 1. Other components and connecting modes are the same as those of the first embodiment or the second embodiment.

The filtering circulation mechanism of the present embodiment has the advantages that the overflow area is very matched with the corner of the aquarium, the space utilization rate is high, and on the other hand, only one hole needs to be drilled at the bottom of the aquarium, and the requirements of water feeding and water discharging are met by the combined pipe fitting 124 for water feeding and water discharging. The bin areas are separated by the partition plates, and the respective functions are completed.

The breed fish bowl rivers in the fish bowl 1 is bred in laboratory in this embodiment pass through overflow area 12, deposit storehouse 2, dry and wet disengagement zone 3 and filter the storehouse district in proper order, and the impurity of effective filtering aquatic, hardness, the pH value of regulating reservoir etc. decompose various organic waste such as aquatic ammonia nitrogen, nitrite, get into clean water storehouse 8 after handling, return to in the fish bowl 1 is bred in the laboratory again to realize the purification and the cyclic utilization of experiment breed water quality of water.

The fourth concrete implementation mode: referring to fig. 1 to 2, the overflow area 12 of the present embodiment is disposed at a corner of the laboratory aquarium 1, the overflow area 12 includes a flow blocking plate 121 and an overflow plate 122, the flow blocking plate 121 and the overflow plate 122 are vertically and fixedly connected to an inner wall of the laboratory aquarium 1, the flow blocking plate 121 is disposed outside the overflow plate 122, an overflow inlet 125 is disposed between a lower end of the flow blocking plate 121 and a bottom of the laboratory aquarium 1, and an upper end of the overflow plate 122 is lower than an upper end of the flow blocking plate 121. Other components and connection modes are the same as those of the third embodiment.

The overflow area 12 in this embodiment is a four-corner overflow area, which can make full use of the space in the laboratory aquaculture fish tank 1, a hole is opened on the bottom surface in the overflow area 12, which is used as the bottom water outlet end of the overflow area 12, a gap is provided between the flow baffle 121 and the overflow plate 122, the aquaculture fish tank water flow enters the gap between the flow baffle 121 and the overflow plate 122 through the overflow inlet 125 at the lower end of the flow baffle 121, enters the overflow area 12 through the upper end of the overflow plate 122, and then flows out through the bottom water outlet end of the overflow area 12.

In this embodiment, the upper end of the baffle 121 is lower than the side wall of the aquarium 1 and higher than the upper end of the overflow plate 122.

The fifth concrete implementation mode: with reference to fig. 1 to 2, the settling bin 2 of the present embodiment is disposed at the lower end of a laboratory culture fish tank 1, the settling bin 2 includes a sewer pipe 21, a funnel sedimentation tank 24 and a plurality of slow flow baffles 23, the bottom water outlet end of an overflow area 12 is connected to the water inlet end of the settling bin 2 through the sewer pipe 21, the water inlet end of the settling bin 2 is disposed at the top end, the funnel sedimentation tank 24 is disposed at the bottom end, the slow flow baffles 23 are disposed at the upper end of the funnel sedimentation tank 24 along the height direction in a staggered manner, each slow flow baffle 23 is disposed along the horizontal direction, the water outlet end of the settling bin 2 is disposed at the upper end, and the bottom end of the funnel sedimentation tank 24 is connected to a sewage discharge pipe. Other components and connection modes are the same as those of the third embodiment.

The breed fish bowl rivers flow out through the bottom of overflow district 12 in this embodiment goes into through downcomer 21 and deposits storehouse 2 in order to deposit the residue in order to deposit the storehouse 2, and deposit storehouse 2 and include three longitudinal arrangement's funnel sedimentation tank 24, and first funnel sedimentation tank 24 sets up the below at downcomer 21, and breed fish bowl rivers are deposited the mode of back through the overflow and are got into second funnel sedimentation tank 24 and third funnel sedimentation tank 24 successively to go into dry wet separation zone 3 by the play water end of third funnel sedimentation tank 24. The funnel-type settling tank 24 is constructed to swirl the water flow and to cause solids to be spun by centrifugal force into the vicinity of the underflow pipe, where they are sucked into the underflow pipe during the blowdown. A flow speed regulating valve 22 can be additionally arranged on the sewer pipe 21 to reduce the water flow speed, and a plurality of slow flow baffles 23 can further reduce the flow speed so as to facilitate the deposition of residues such as excrement, residual food, harmful impurities and the like and reduce the burden of filter cotton. The residue deposits in the funnel sedimentation tank 24, is discharged through the sewage pipes 92 after accumulating a certain amount, and the bottom end of the funnel sedimentation tank 24 can be added with a forced discharge valve 91 so as to discharge the residue periodically.

The sixth specific implementation mode: with reference to fig. 1 and fig. 2, in the present embodiment, the dry-wet separation zone 3 is disposed at an upper portion of one side of the precipitation bin 2, the dry-wet separation zone 3 includes a shower plate 31 and a plurality of drawer-type shower grooves 32, the shower plate 31 is horizontally disposed, a water inlet end of the dry-wet separation zone 3 is disposed at an upper end of the shower plate 31, a water outlet end of the precipitation bin 2 is connected to a water inlet end of the dry-wet separation zone 3, the plurality of drawer-type shower grooves 32 are horizontally disposed at a lower end of the shower plate 31, a plurality of water leakage holes are densely distributed at bottoms of the shower plate 31 and the drawer-type shower grooves 32, a filter cotton layer is laid in the drawer-type shower grooves 32, the drawer-type shower grooves 32 can be pulled and retracted in a horizontal direction, and a water outlet end of the dry-wet separation zone 3 is disposed at a lower. The other components and the connection mode are the same as the fifth embodiment mode.

In the embodiment, the water after being precipitated and discharged is overflowed from the water outlet end of the precipitation bin 2 to enter the water inlet end of the dry-wet separation zone 3, and flows into the plurality of drawer-type rain grooves 32 in a trickling manner after being dispersed and slowly flowed by the rain plates 31, the filter cotton layer is placed in the drawer-type rain grooves 32, and the filtered water flows out in a trickling manner to enter the water outlet end of the dry-wet separation zone 3. The drawer deluge tank 32 can be pulled and retracted horizontally to facilitate periodic cleaning and replacement of the filter cotton layer.

The seventh embodiment: with reference to fig. 1 and fig. 2, the filtering bin zone of the present embodiment is disposed at the lower portion of one side of the settling bin 2, the filtering bin zone includes a physical filtering bin 4, a chemical filtering bin 5, and a biological filtering bin 6, and the physical filtering bin 4, the chemical filtering bin 5, and the biological filtering bin 6 are sequentially disposed from first to last. Other components and connection modes are the same as those of the sixth embodiment.

In the embodiment, the physical filtration bin 4, the chemical filtration bin 5 and the biological filtration bin 6 are horizontally arranged in parallel, the water inlet end of the physical filtration bin 4 is arranged at the upper end, the water outlet end of the dry-wet separation zone 3 is connected with the water inlet end of the physical filtration bin 4, the water outlet end of the physical filtration bin 4 is arranged at the lower end, the water inlet end of the chemical filtration bin 5 is arranged at the upper end, the water outlet end of the physical filtration bin 4 is connected with the water inlet end of the chemical filtration bin 5, the water outlet end of the chemical filtration bin 5 is arranged at the lower end, the water inlet end of the biological filtration bin 6 is arranged at the upper end, the water outlet end of the chemical filtration bin 5 is connected with the water inlet end of the biological filtration bin 6, and the water outlet.

In the embodiment, the physical filtering bin 4, the chemical filtering bin 5 and the biological filtering bin 6 are separated by two clapboards, water enters the chemical filtering bin 5 for filtering in an overflow mode after being filtered by the physical filtering bin 4, and then enters the biological filtering bin 6 for filtering in the overflow mode. The physical filtering chamber 4 is filled with filter materials matched with black and white cotton, magic blankets, cashmere cotton and other coarse and fine materials, the chemical filtering chamber 5 is filled with filter materials such as activated carbon, soft water resin, ceramic rings, coral sand and the like for adjusting the hardness, pH value and the like of water, and the biological filtering chamber 6 is filled with biological filter materials such as biological balls, glass rings, bacteria rooms and the like, and various organic wastes such as ammonia nitrogen, nitrite and the like in the water are decomposed by bacteria culture of the filter materials.

In this embodiment, an oxygen disk 51 is disposed between the chemical filtering bin 5 and the biological filtering bin 6 so as to enhance the dissolved oxygen in water, effectively improve the biological treatment capacity of organic waste in the decomposed water, and meet the growth requirements of aquatic animals.

The specific implementation mode is eight: referring to fig. 1 to 2, the bottom ends of the physical filtration cabin 4, the chemical filtration cabin 5 and the biological filtration cabin 6 in this embodiment are connected to a sewage pipe 92. The other components and the connection mode are the same as those of the seventh embodiment.

The design is that the residue deposited at the bottom ends of the physical filtering bin 4, the chemical filtering bin 5 and the biological filtering bin 6 can be discharged timely through the sewage discharge pipeline 92. In this embodiment, the forced-discharge valve 91 may be disposed at the bottom ends of the physical filtration chamber 4, the chemical filtration chamber 5, and the biological filtration chamber 6, so as to perform periodic cleaning.

The specific implementation method nine: as described with reference to fig. 1 to 2, the filtration circulation mechanism according to the present embodiment further includes a heating chamber 7, the heating chamber 7 is disposed at the front end of the clean water chamber 8, and an electric heating rod 71 is disposed in the heating chamber 7. Other compositions and connection modes are the same as those of the third, fourth, fifth, sixth, seventh or eighth embodiment.

In the embodiment, the filtered water enters the heating chamber 7, the electric heating rod 71 is arranged in the heating chamber 7, the temperature of the bottom of the laboratory culture fish tank 1 is detected according to the multi-position detection module 116 when the laboratory culture fish tank is used, the temperature is fed back to the controller, and the temperature rise and fall or the closing and the like are controlled according to the preset range so as to keep the proper temperature for the experimental culture control.

The water inlet end of the heating bin 7 is arranged at the lower end, the water outlet end of the filtering bin area is connected with the water inlet end of the heating bin 7, the water outlet end of the heating bin 7 is arranged at the upper end, and the water outlet end of the heating bin 7 is connected with the water inlet end of the purified water bin 8. The water in the heating bin 7 is designed to flow out to the purified water bin 8 in an overflow mode so as to ensure that the temperature of the outlet water is within a preset range.

The detailed implementation mode is ten: with reference to fig. 1 to 2, the clean water reservoir 8 of the present embodiment includes a water pump water pipe 81 and a water pump 82, the water pump 82 is disposed in the clean water reservoir 8, a water inlet end of the water pump water pipe 81 is connected to a water outlet end of the water pump 82, and a water outlet end of the water pump water pipe 81 is disposed in the laboratory culture fish tank 1. The other components and the connection mode are the same as the fifth embodiment mode.

The water outlet end of the water pump water supply pipe 81 in the embodiment can be directly arranged in the laboratory culture fish tank 1 and arranged outside the overflow area 12, and the water pump 82 directly pumps out the water in the purified water bin 8 into the laboratory culture fish tank 1. In addition, a water supply pipe 123 can be arranged in the laboratory culture fish tank 1, and the water outlet end of the water supply pipe 123 is arranged outside the overflow area 12, so that purified water is circularly supplemented to the laboratory culture fish tank 1. In order to facilitate the connection between the water pipes, the bottom of the overflow area 12 can be provided with a water feeding and discharging combined pipe fitting 124, the bottom of the overflow area 12 is provided with a hole, the water feeding and discharging combined pipe fitting 124 is inserted into the inner side of the hole, the water feeding and discharging combined pipe fitting 124 and the hole are sealed, the water feeding and discharging combined pipe fitting 124 comprises an inner pipe and an outer pipe, the inner pipe is fixed at one side of the outer pipe, the water inlet end of the sewer pipe 21 is connected with the outer side end of the outer pipe, the outer pipe is the water outlet end of the overflow area, and the water inlet end of the water feeding pipe 123 is connected with.

The bottom end of the clean water tank 8 is connected to a sewage pipe 92, and a forced-discharge valve 91 may be provided at the bottom end of the clean water tank 8 for periodic cleaning.

Although the invention herein has been described with reference to particular embodiments, it is to be understood that these embodiments are merely illustrative of the principles and applications of the present invention. It is therefore to be understood that numerous modifications may be made to the illustrative embodiments and that other arrangements may be devised without departing from the spirit and scope of the present invention as defined by the appended claims. It should be understood that features described in different dependent claims and herein may be combined in ways different from those described in the original claims. It is also to be understood that features described in connection with individual embodiments may be used in other described embodiments.

Claims (10)

1. The utility model provides a laboratory intelligence aquatic animals farming systems which characterized in that: the aquarium breeding system comprises a laboratory breeding fish tank (1), a lighting mechanism (111), an automatic feeding mechanism (112), a water level sensor (113), an oxygenation mechanism (114), a dissolved oxygen detection module (115), a multi-position detection module (116), an illumination sensor (117), a filtering circulation mechanism and a controller, wherein the lighting mechanism (111) is arranged at the upper end of the laboratory breeding fish tank (1), the automatic feeding mechanism (112) is arranged at one side of the upper end of the laboratory breeding fish tank (1), the water level sensor (113) is arranged on the side wall of the laboratory breeding fish tank (1), the oxygenation mechanism (114), the dissolved oxygen detection module (115), the multi-position detection module (116) and the illumination sensor (117) are arranged at the bottom of the laboratory breeding fish tank (1), the laboratory breeding fish tank (1) is connected with the filtering circulation mechanism, the lighting mechanism (111), The automatic feeding mechanism (112), the water level sensor (113), the oxygenation mechanism (114), the dissolved oxygen detection module (115), the multi-position detection module (116), the illumination sensor (117) and the filtering circulation mechanism are all connected with the controller.

2. The laboratory intelligent aquarium culture system of claim 1, wherein: the multi-position detection module (116) is a four-in-one detection module for temperature, pH value, total dissolved solid amount and conductivity.

3. A laboratory intelligent aquarium culture system as defined in claim 1 or 2 wherein: filtration circulation mechanism includes overflow district (12), deposits storehouse (2), dry wet disengagement zone (3), crosses filter storehouse district and clean water storehouse (8), overflow district (12) set up in fish bowl (1) is bred in the laboratory, the bottom of overflow district (12) is gone out the water end and is held with the end of intaking that deposits storehouse (2) and be connected, deposit the water of storehouse (2) play water end and enter clean water storehouse (8) by first to the back through dry wet disengagement zone (3) and cross the filter storehouse district in proper order, the play water end of clean water storehouse (8) is held with the end of intaking that fish bowl (1) was bred in the laboratory is connected.

4. The laboratory intelligent aquarium culture system of claim 3, wherein: the overflow area (12) is arranged at one corner in the laboratory culture fish tank (1), the overflow area (12) comprises a baffle plate (121) and an overflow plate (122), the baffle plate (121) and the overflow plate (122) are vertically and parallelly fixedly connected to the inner wall of the laboratory culture fish tank (1), the baffle plate (121) is arranged on the outer side of the overflow plate (122), an overflow inlet (125) is arranged between the lower end of the baffle plate (121) and the bottom of the laboratory culture fish tank (1), and the upper end of the overflow plate (122) is lower than the upper end of the baffle plate (121).

5. The laboratory intelligent aquarium culture system of claim 3, wherein: deposit storehouse (2) and set up the lower extreme of breeding fish bowl (1) in the laboratory, it includes downcomer (21) to deposit storehouse (2), funnel sedimentation tank (24) and a plurality of unhurried current baffle (23), the bottom of overflow district (12) is gone out the water end and is passed through downcomer (21) with the end of intaking of depositing storehouse (2) and be connected, the end of intaking of depositing storehouse (2) sets up on the top, funnel sedimentation tank (24) set up in the bottom, a plurality of unhurried current baffles (23) are along the crisscross upper end that sets up in funnel sedimentation tank (24) of direction of height, every unhurried current baffle (23) all set up along the level, the play water end of depositing storehouse (2) sets up in the upper end, the bottom of funnel sedimentation tank (24) is connected with sewage pipes (92.

6. The laboratory intelligent aquarium culture system of claim 5, wherein: the dry-wet separation zone (3) is arranged at the upper part of one side of the precipitation bin (2), the dry-wet separation zone (3) comprises a rain plate (31) and a plurality of drawer-type rain grooves (32), the rain plate (31) is horizontally arranged, the water inlet end of the dry-wet separation zone (3) is arranged at the upper end of the rain plate (31), the water outlet end of the precipitation bin (2) is connected with the water inlet end of the dry-wet separation zone (3), the drawer-type rain grooves (32) are horizontally arranged at the lower end of the rain plate (31) in parallel, a plurality of water leakage holes are uniformly distributed and densely arranged on the bottoms of the rain plate (31) and the drawer-type rain grooves (32), a filtering cotton layer is paved in the drawer-type rain grooves (32), the drawer-type rain grooves (32) can be pulled and retracted along the horizontal direction, and the water outlet end of the dry-wet separation zone (3) is arranged at the lower end of the drawer-type rain grooves.

7. The laboratory intelligent aquarium culture system of claim 6, wherein: the filtering bin area is arranged at the lower part of one side of the settling bin (2), the filtering bin area comprises a physical filtering bin (4), a chemical filtering bin (5) and a biological filtering bin (6), and the physical filtering bin (4), the chemical filtering bin (5) and the biological filtering bin (6) are sequentially arranged from beginning to end.

8. The laboratory intelligent aquarium culture system of claim 7, wherein: the bottom ends of the physical filtering bin (4), the chemical filtering bin (5) and the biological filtering bin (6) are all connected with a sewage discharge pipeline (92).

9. The laboratory intelligent aquarium culture system of claim 3, wherein: the filtering circulation mechanism further comprises a heating bin (7), the heating bin (7) is arranged at the front end of the purified water bin (8), and an electric heating rod (71) is arranged in the heating bin (7).

10. The laboratory intelligent aquarium culture system of claim 3, wherein: the purified water bin (8) comprises a water pump water feeding pipe (81) and a water pump (82), the water pump (82) is arranged in the purified water bin (8), the water inlet end of the water pump water feeding pipe (81) is connected with the water outlet end of the water pump (82), and the water outlet end of the water pump water feeding pipe (81) is arranged in the laboratory culture fish tank (1).

Images