CN112772521A - Artificial intelligent interconnected seafood pool operation system for aquaculture equipment - Google Patents

Abstract

The invention discloses an artificial intelligence interconnected seafood pool operation system for aquaculture equipment, and relates to the technical field of aquaculture equipment. The invention comprises a multi-cylinder interconnected seawater proportioning system and an extension aquaculture system connected with the multi-cylinder interconnected seawater proportioning system. The system is formed by connecting a multi-port seawater proportioning system and a plurality of devices in parallel, realizes multi-proportioning of one machine, solves the problem of difficulty in proportioning seawater and supplementing seawater in the industry, reduces the operation cost of manual management of the devices through centralized control of network ports, reduces a single-machine control panel, does not need manual management, reduces the operation cost of customers, can monitor the salinity change of the devices in real time, saves the situation that a plurality of products are difficult to control manually, and is more accurate in salinity control. The survival rate of the temporary culture product is increased, the function of supplementing seawater can be realized, and the problem of artificial seawater supplementation is solved.

Description

Artificial intelligent interconnected seafood pool operation system for aquaculture equipment

Technical Field

The invention belongs to the technical field of aquaculture equipment, and particularly relates to an artificial intelligent interconnected seafood pool operation system for the aquaculture equipment.

Background

Aquaculture equipment is like fish bowl and fish pond, and the general filtration mode adopts external filter vat to filter, through in the external filter vat that inserts of water with fish bowl or fish pond, converges into the fish pond after being filtered by the filter vat and forms the circulation. However, in the water circulation process, only partial impurities can be filtered by the filtration of the filter barrel, and the impurities cannot be precipitated and filtered, so that the filtering effect is poor. Traditional box filter vat, manual operation back filter media do not put the reduction and easily lead to the product to filter not in place, and current equipment adopts numerous traditional manual valve, and the operation workman does not make the function of each valve, easy maloperation.

Because of the complexity and instability of natural seawater, artificial seawater is often used to replace natural seawater in fish ponds for feeding organisms. At present, some countries adopt 'artificial fast sea salt' to prepare artificial sea water, the artificial sea water keeps organic substances in natural sea water similar to natural sea water, and marine organisms can be successfully raised. According to different organisms fed, water with different salinity is needed in the fish pond, and the existing equipment is difficult to meet the production and living requirements.

An artificial intelligence interconnected seafood pool operation system for aquaculture equipment is provided, and the problems are solved.

Disclosure of Invention

The invention aims to provide an artificial intelligence interconnected seafood pool operation system for aquaculture equipment, wherein a traditional manual valve is replaced by an electric valve, a traditional box-type filter barrel is replaced by a closed filter barrel, a vacuum pumping circulation principle is adopted in an equipment filtering circulation system, a physical principle is utilized, a front fish scale sundries filter is additionally arranged, heavy objects sink by slowing down water flow and are left in the front filter to not participate in filtering, so that the filter material is ensured not to be polluted by sundries, and each water outlet interface is connected with an extension machine through the arrangement of a storage chamber, a salt storage chamber, a distributor and a mixing chamber, so that multi-cylinder interconnection is realized, and the existing problem is solved.

In order to solve the technical problems, the invention is realized by the following technical scheme:

the invention relates to an artificial intelligence interconnected seafood pool operation system for aquaculture equipment, which comprises a multi-cylinder interconnected seawater proportioning system and an extension aquaculture system connected with the multi-cylinder interconnected seawater proportioning system;

the multi-cylinder interconnected seawater proportioning system comprises: a storage chamber; the salt storage chamber is communicated with the accommodating chamber through a water inlet pipe II; the mixing chamber is communicated with the accommodating chamber through a water inlet pipe II, and the mixing chamber is communicated with the salt storage chamber through a water inlet pipe III; the distributor is communicated with the mixing chamber through a fourth water inlet pipe; the storage chamber is provided with a plurality of water inlet interfaces, and the water inlet interfaces are connected with the first water inlet pipe; the distributor is provided with a plurality of water outlet interfaces, and the water outlet interfaces are connected with the first water outlet pipe; a first partition plate assembly and a second partition plate assembly are sequentially arranged in the salt storage chamber from bottom to top, and an alarm probe is also arranged in the salt storage chamber; a mixer is arranged in the mixing chamber and comprises turbine blades and impeller blades; the water inlet pipe II is provided with a water pump I and an electromagnetic valve;

the extension farming systems include: a cylinder body and an oxygenation air pump; the tank body comprises three layers of fish tanks, the bottom of each layer of fish tank is provided with a fish scale collector, and the oxygenation air pump is respectively connected with the three layers of fish tanks through three oxygenation pipes; the outlet of the fish scale collector is connected with a drain pipe, and the drain pipe on the fish scale collector positioned at the lowest part is connected to the bottom of a precipitation sterilization coarse filter; the sewage pipes on the two fish scale collectors positioned above are connected with a sewage pipe at the outlet of the sedimentation sterilization coarse filter after being converged; one side of the cylinder body is also provided with a positioning barrel which is connected with a protein separator through a pipeline; the protein separator is connected with a water bubble separator through a pipeline; the protein separator is also connected with a refrigerator through a pipeline, and the pipeline is provided with an ejector; the refrigerator is connected with a water pump through a pipeline; the liquid treated by the precipitation sterilization coarse filter flows into a transparent filter through a pipeline, and the liquid treated by the transparent filter flows into a filter barrel group through a pipeline; the filter barrel group is respectively connected with the refrigerator and the water pump through a drain pipe; the uppermost part of the cylinder body and the water pump are both connected with a water replenishing pipe; the water replenishing pipe at the top of the cylinder body is connected with the first water outlet pipe, and a seawater replenishing valve P2 is installed on the water replenishing pipe; a water replenishing pipe on the water pump is connected with the first water inlet pipe, and a seawater replenishing valve P1 is arranged on the water replenishing pipe; the water replenishing pipe, the oxygen replenishing pipe, the water draining pipe and the sewage draining pipe are all provided with electric valves.

Furthermore, each water outlet interface is connected with a cylinder body.

Further, baffle subassembly one is including installing the filter plate in the salt storage chamber, divide into a plurality of filtering area through the blend stop on the filter plate, each all be equipped with a filter screen, a plurality of in the filtering area the mesh number of filter screen is all different.

Furthermore, the first partition plate assembly also comprises baffle plates which are matched and corresponding to each filtering area respectively, and each baffle plate is arranged on a corresponding barrier strip through a telescopic piece; the side surface of the baffle is also provided with a guide block, and the inner wall of the salt storage chamber is provided with a guide groove which is matched and corresponding to the guide block; and the baffle is also provided with a rubber ring corresponding to each filtering area.

Further, install the bactericidal lamp of a vertical setting in the preliminary filter that disinfects of sediment, the bottom of bactericidal lamp is provided with the movable sleeve, the week side of movable sleeve installs trash holding guide vane.

Furthermore, a horizontal exhaust top valve is arranged above the transparent filter.

Further, the filter vat set comprises two filter vats; the upper part of one of the filter barrels is connected with the outlet of the transparent filter through a sewage discharge pipe, and the bottom of the filter barrel is connected with the upper part of the other filter barrel through a drain pipe.

Further, the upper portion of the filter vat that is connected with transparent filter is still connected with the water pump through moisturizing pipe, and the inside packing of filter vat has the filter media.

Furthermore, check valves are arranged on the sewage discharge pipe connected with the transparent filter and the drain pipe connected with the refrigerator.

Furthermore, the system also comprises a salinity detection unit, a comprehensive analysis unit, a self-identification unit, a salinity planning unit, a volume determination unit, a processor, a display unit and a valve control unit;

the salinity detection unit is arranged in the distributor and used for measuring salinity information in the distributor in real time and marking the salinity information as salinity information to be diluted, the salinity detection unit is used for transmitting the salinity information to be diluted to the comprehensive analysis unit, and the comprehensive analysis unit receives the salinity information to be diluted transmitted by the salinity detection unit;

the self-identification unit is arranged in the corresponding cylinder body and used for identifying marine products in the cylinder body and marking the obtained marine products as audience object information, the self-identification unit is used for transmitting the audience object information to the salinity planning unit, the salinity planning unit receives the audience object information transmitted by the self-identification unit and performs self-planning analysis, and the specific analysis steps are as follows:

the method comprises the following steps: firstly, acquiring all audience object information, and marking the audience object information as Zi, i-1.. n;

step two: acquiring the proper salinity ranges of all the audience object information Zi, and marking the salinity ranges as Fi, i-1.. n;

step three: then, acquiring the cross range of all the Fi, and marking the cross range as a proper salinity area when all the Fi has the cross range; automatically taking the median value of the suitable salinity area, and marking the median value as target salinity regulation;

step four: if all the Fi do not have the same intersection range, performing circle division processing, specifically processing steps of:

s1: the method comprises the steps that the Fi with the common range is divided into the same range group, and the Fi is divided under the condition that the number of the range groups is the minimum;

s2: all range groups were obtained and labeled Wj, j 1.. m;

s3: automatically obtaining a median value for all range groups, which is labeled Wzj, j 1.. m; wzj correspond to Wj one-to-one;

s4: then, calculating the average value of all the median values, and marking the value as a target value;

s5: subtracting the target value from Wzj, and if the obtained difference value exceeds X1 and X1 is a user preset numerical value, correspondingly deleting Wzj;

s6: carrying out average value solving on the residual Wzj, and marking the obtained average value as a target value;

s7: automatically searching the death rate of all marine products in the corresponding cylinder under the condition of the target value, and marking the marine products with the death rate exceeding X2 as removal objects; x2 is a preset value;

step five: transmitting the removal object and the target value to the comprehensive analysis unit;

the comprehensive analysis unit receives the removal object and the target value transmitted by the salinity planning unit; the volume measuring unit is used for measuring the volume of the cylinder body and transmitting the volume to the comprehensive analysis unit;

the comprehensive analysis unit is used for carrying out valve control time period analysis by combining the volume of the cylinder body, the target value and the information of the salinity to be diluted, and the specific analysis steps are as follows:

s01: obtaining a target value, information of salinity to be diluted and the volume of the cylinder body;

s02: automatically measuring to obtain salinity information and water volume information in the existing cylinder body;

s03: according to the target value, automatically acquiring the volume of water required in the cylinder body, correspondingly acquiring the amount of seawater added with the salinity information to be diluted, and under the condition that the total amount of water in the cylinder body is less than the volume X3 of the cylinder body, acquiring the amount of seawater additionally added with the salinity information to be diluted; simultaneously, automatically acquiring the adjustment quantity of the water volume in the cylinder body, wherein the adjustment quantity comprises an increase quantity or a decrease quantity;

s04: obtaining adjustment information;

s05: adjusting the original water quantity in the cylinder body;

s06: then obtaining the volume of the seawater volume of the salinity information to be diluted which needs to be increased;

s07: automatically acquiring the water discharge amount of a water outlet pipe in unit time;

s08: dividing the volume of the seawater by the water discharge amount in unit time to obtain water discharge time;

the comprehensive analysis unit is used for transmitting the water discharging time to the processor, and the processor is used for driving the control valve control unit to open the water discharging time corresponding to the valve for water discharging;

the processor is used for transmitting the water discharging time to the display unit for real-time display.

The invention has the following beneficial effects:

the electromagnetic valve replaces the traditional manual valve, so that the problems that the number of equipment valves is large, the functions of all the valves are not obscured by operators and misoperation is easy to occur are avoided; the closed filter barrel is used for replacing a traditional box-type filter barrel, so that manual operation is reduced, and the phenomenon that the product is not filtered in place due to the fact that filter materials are not placed and reduced after manual operation is avoided; the filtering and circulating system adopts a vacuum pumping and circulating principle, is additionally provided with a transparent filter and a horizontal exhaust top valve, utilizes horizontal pressure when adding water to jack the valve for exhausting, and compresses an exhaust port when a water pump absorbs water to enable the filtering to form vacuum state operation, so that the problem of water shortage of the water pump is solved, and the equipment ensures that all water is completely filtered; by utilizing the physical principle, a preposed fish scale sundries filter is additionally arranged, heavy objects sink by slowing down water flow, and the heavy objects are left in the preposed filter and do not participate in filtering, so that the filter material is ensured not to be polluted by sundries;

the water is stored in the storage chamber, the salt storage chamber is communicated with the storage chamber through a second water inlet pipe, the mixing chamber is communicated with the storage chamber through a second water inlet pipe, and the mixing chamber is communicated with the salt storage chamber through a third water inlet pipe; the distributor is communicated with the mixing chamber through a water inlet pipe IV; the distributor is provided with a plurality of water outlet ports, a first partition plate assembly and a second partition plate assembly are sequentially arranged in the salt storage chamber from bottom to top, and an alarm probe is further arranged in the salt storage chamber and is formed by connecting a multi-port seawater proportioning system and a plurality of cylinder bodies in parallel, so that the problems of seawater proportioning and seawater supplementing difficulty in the industry are solved.

Of course, it is not necessary for any product in which the invention is practiced to achieve all of the above-described advantages at the same time.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings used in the description of the embodiments will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art that other drawings can be obtained according to the drawings without creative efforts.

FIG. 1 is a schematic structural diagram of an artificial intelligence interconnected seafood pool operating system for an aquaculture apparatus according to the present invention;

FIG. 2 is a schematic structural diagram of a multi-cylinder interconnected seawater proportioning system according to the present invention;

FIG. 3 is a schematic view of the structure at A in FIG. 2;

FIG. 4 is a schematic view of the structure at B in FIG. 2;

FIG. 5 is a schematic view of the structure at C in FIG. 2;

FIG. 6 is a schematic structural diagram of a multi-cylinder interconnected seawater proportioner of the invention;

FIG. 7 is a schematic structural view of a first separator plate assembly according to the present invention;

FIG. 8 is a schematic structural view of a first separator plate assembly according to the present invention;

FIG. 9 is a schematic structural view of a first separator plate assembly according to the present invention;

FIG. 10 is a schematic view of a portion of a first separator plate assembly according to the present invention;

FIG. 11 is a schematic view of a portion of a first baffle plate assembly of the present invention;

FIG. 12 is a system block diagram of a multi-cylinder interconnected seawater proportioning system of the present invention;

FIG. 13 is a schematic structural view of the extension farming system of the present invention;

FIG. 14 is a schematic view of the structure of FIG. 13 at D;

FIG. 15 is a schematic view of the structure at E in FIG. 13;

FIG. 16 is a schematic view of the structure of FIG. 13 at F;

FIG. 17 is a schematic view of a partial structure of the extension farming system of the present invention;

FIG. 18 is a schematic view of a partial structure of the extension farming system of the present invention;

FIG. 19 is a schematic view of a partial structure of the extension farming system of the present invention;

in the drawings, the components represented by the respective reference numerals are listed below:

1-a first water inlet pipe, 2-a receiving chamber, 3-a first water pump, 4-an electromagnetic valve, 5-a second water inlet pipe, 6-a first partition component, 7-a salt storage chamber, 8-a second partition component, 9-a cover plate, 10-a distributor, 11-a first water outlet pipe, 12-an alarm probe, 13-a mixing chamber, 14-a mixer, 15-a turbine blade, 16-an impeller blade, 17-a central control screen, 18-a shell, 19-a third water inlet pipe, 20-a fourth water inlet pipe, 201-a water inlet interface, 601-a filter plate, 6011-a filter screen, 6012-a barrier strip, 602-a baffle, 6021-a rubber ring, 603-a guide block, 604-a telescopic piece and 1001-a water outlet interface; 01-cylinder body, 02-filter cover, 03-fish scale collector, 04-sedimentation sterilization coarse filter, 0401-sterilizing lamp, 0402-trash holding guide vane, 05-transparent filter, 0501-horizontal exhaust top valve, 06-filter barrel, 071-oxygen control valve Q1, 072-oxygen control valve Q2, 073-oxygen control valve Q3, 081-blowdown electric valve B1, 082-blowdown electric valve B2, 083-blowdown electric valve B3, 084-blowdown electric valve B4, 085-blowdown electric valve B5, 091-operation control valve A1, 092-operation control valve A2, 093-operation control valve A3, 094-operation control valve A4, 0101-seawater water supplement valve P1, 0102-seawater supplement valve P2, 011-check valve, 012-water pump, 013-albumen separator, 014-bubble separator, 015-ejector, 016-oxygenation air pump, 017-refrigerator, 018-positioning barrel, 01801-positioning switch, 019-watering electromagnetic valve, 020-oxygenation pipe, 021-drainage pipe, 022-drainage pipe and 023-water replenishing pipe.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In the description of the present invention, it is to be understood that the terms "left", "upper", "lower", "right", "top", "middle", "inner", "rear", "side", "end", "bottom", and the like, indicate orientations or positional relationships and are used merely to facilitate the description of the present invention and to simplify the description, but do not indicate or imply that the referenced components or elements must have a particular orientation, be constructed and operated in a particular orientation, and thus are not to be construed as limiting the present invention.

Referring to fig. 1-19, the present invention is an artificial intelligence interconnected seafood pool operation system for aquaculture equipment, which comprises a multi-cylinder interconnected seawater proportioning system, a central control screen 17 is installed on a housing 18 of the multi-cylinder interconnected seawater proportioning system for facilitating the control of the whole equipment, and the housing 18 is internally provided with: the storage chamber 2 is used for storing purified water; the salt storage chamber 7 is communicated with the accommodating chamber 2 through a water inlet pipe II 5; the mixing chamber 13 is communicated with the accommodating chamber 2 through a second water inlet pipe 5, and the mixing chamber 13 is communicated with the salt storage chamber 7 through a third water inlet pipe 19; the distributor 10 is communicated with the mixing chamber 13 through a water inlet pipe four 20; as shown in fig. 2, the receiving chamber 2 is provided with six water inlet ports 201, and the water inlet ports 201 are connected with the first water inlet pipe 1; the distributor 10 is provided with six water outlet connectors 1001, the water outlet connectors 1001 are connected with a first water outlet pipe 11, and the cylinder body 01 is communicated with the distributor 10 through the first water outlet pipe 11; the water inlet pipe II 5 is provided with the water pump I3 and the electromagnetic valve 4, purified water flows into the storage chamber 2 through the water inlet pipe I1 and then is pumped into the salt storage chamber 7 through the water pump I3, salt in the salt storage chamber 7 is dissolved, salt water flows into the mixing chamber 13 through the water inlet pipe III 19 and flows into the distributor 10 after being stirred, each water outlet port 1001 is connected with one cylinder body 01, and the salt water flows into each cylinder body 01 through the distributor 10, so that the operation cost of manually arranging equipment is reduced, a single-machine control panel is reduced, manual arrangement is not needed, and the operation cost of customers is reduced; the multi-port seawater proportioning system is formed by connecting a plurality of extension devices in parallel, so that multi-proportioning of one machine is realized, and the problems of seawater proportioning and seawater supplement difficulty in the industry are solved; can reduce the operation cost that equipment was managed by the manual work through network port centralized control, reduce single control panel, need not the manual work and manage, reduce customer operation cost, entire system can accomplish the salinity change of real time monitoring to many equipment, has saved the manual situation that is difficult to control of a plurality of saltiness of many products, and control saltiness is more accurate. The survival rate of the temporary culture product is increased, the function of supplementing seawater can be realized, and the problem of artificial seawater supplementation is solved.

As shown in fig. 2, the second water inlet pipe 5 is a T-shaped pipe, and two water outlet ends (an upper end and a left end shown in fig. 2) and one water inlet end (a lower end shown in fig. 2) are arranged in three ports of the T-shaped pipe; the water inlet end of the T-shaped pipe is connected with the containing chamber 2, one water outlet end (an upper port shown in figure 2) of the T-shaped pipe is connected with the salt storage chamber 7, the other water outlet end (a left port shown in figure 2) of the T-shaped pipe is connected with the mixing chamber 13, a solenoid valve 4 is installed on a branch pipe of the T-shaped pipe connected with the salt storage chamber 7, a water pump I3 is installed on the branch pipe of the T-shaped pipe connected with the containing chamber 2, a cover plate 9 is installed on the salt storage chamber 7, and brine and purified water flow into the mixing chamber 13 through a water inlet pipe II 5 and a water inlet pipe III 19 respectively, so that salt is dissolved more fully, and simultaneously the salinity of the brine can be further adjusted through the purified water.

As shown in fig. 2 and 3, a mixer 14 is installed in the mixing chamber 13, and the mixer 14 comprises turbine blades 15 and impeller blades 16; impeller blade 16 installs in turbine blade 15 below, strikes impeller blade 16 through the backward flow and drives turbine blade 15 and rotate and make the liquid in the mixing chamber 13 form the vortex, and it is more abundant to make salt solution dissolve through the stirring, utilizes hydrodynamic force to promote impeller blade 16 and drives turbine blade 15 and form the vortex, utilizes hydrodynamic force to give the salt storage chamber 7 water injection simultaneously, makes salt melt, and the following current flows to the mixing chamber, and the salt is shunted to required extension equipment by distributor 10 after dissolving.

As shown in fig. 2, a first partition plate assembly 6 and a second partition plate assembly 8 are sequentially arranged in the salt storage chamber 7 from bottom to top, impurities are filtered through the second partition plate assembly 8, and an alarm probe 12 is also arranged in the salt storage chamber 7 and can give an alarm in time; as shown in fig. 7-11, the first partition plate assembly 6 includes a filter plate 601 installed in the salt storage chamber 7, the filter plate 601 is divided into four filtering regions by barrier strips 6012, each filtering region is provided with a filter screen 6011, the mesh number of the four filter screens 6011 is different, the first partition plate assembly 6 further includes a baffle 602 corresponding to each filtering region, each baffle 602 is installed on the corresponding barrier strip 6012 by a telescopic member 604, the side surface of the baffle 602 is further provided with a guide block 603, the inner wall of the salt storage chamber 7 is provided with a guide groove corresponding to the guide block 603, so that the baffle 602 slides up and down more stably, the baffle 602 is further provided with a rubber ring 6021 corresponding to each filtering region, when the filtering region is not used, the leakage of the filtering region is avoided by the rubber ring 6021, one or more baffles 602 can be selected and lifted according to the particle size of salt and the dissolving requirement, thereby controlling the dissolution degree of the brine.

As shown in fig. 12, the method further includes: the device comprises a salinity detection unit, a comprehensive analysis unit, a self-identification unit, a salinity planning unit, a volume measurement unit, a processor, a display unit and a valve control unit, wherein the cylinder body 01 is controlled by the processor in an interconnection manner, so that the survival rate of temporary culture products is increased, the function of supplementing seawater can be realized, and the problem of artificial seawater supplementation is solved;

the salinity detection unit is arranged in the distributor and used for measuring salinity information in the distributor in real time and marking the salinity information as salinity information to be diluted, the salinity detection unit is used for transmitting the salinity information to be diluted to the comprehensive analysis unit, and the comprehensive analysis unit receives the salinity information to be diluted transmitted by the salinity detection unit;

the self-identification unit is arranged in the corresponding cylinder body 01 and used for identifying marine products in the cylinder body 01, the obtained marine products are marked as audience object information, the self-identification unit is used for transmitting the audience object information to the salinity planning unit, the salinity planning unit receives the audience object information transmitted by the self-identification unit and performs self-planning analysis, and the specific analysis steps are as follows:

the method comprises the following steps: firstly, acquiring all audience object information, and marking the audience object information as Zi, i-1.. n;

step two: acquiring the proper salinity ranges of all the audience object information Zi, and marking the salinity ranges as Fi, i-1.. n;

step three: then, acquiring the cross range of all the Fi, and marking the cross range as a proper salinity area when all the Fi has the cross range; automatically taking the median value of the suitable salinity area, and marking the median value as target salinity regulation;

step four: if all the Fi do not have the same intersection range, performing circle division processing, specifically processing steps of:

s1: the method comprises the steps that the Fi with the common range is divided into the same range group, and the Fi is divided under the condition that the number of the range groups is the minimum;

s2: all range groups were obtained and labeled Wj, j 1.. m;

s3: automatically obtaining a median value for all range groups, which is labeled Wzj, j 1.. m; wzj correspond to Wj one-to-one;

s4: then, calculating the average value of all the median values, and marking the value as a target value;

s5: subtracting the target value from Wzj, and if the obtained difference value exceeds X1 and X1 is a user preset numerical value, correspondingly deleting Wzj;

s6: carrying out average value solving on the residual Wzj, and marking the obtained average value as a target value;

s7: automatically searching for the mortality rate of all marine products in the cylinder 01 corresponding to the target value, and marking the marine products with the mortality rate exceeding X2 as objects to be removed; x2 is a preset value;

step five: transmitting the removal object and the target value to the comprehensive analysis unit;

the comprehensive analysis unit receives the removal object and the target value transmitted by the salinity planning unit; the volume measuring unit is used for measuring the volume of the cylinder body 01 and transmitting the volume to the comprehensive analysis unit;

the comprehensive analysis unit is used for carrying out valve control time period analysis by combining the volume of the cylinder body 01, a target value and information of salinity to be diluted, and comprises the following specific analysis steps:

s01: obtaining a target value, information of salinity to be diluted and the volume of the cylinder body 01;

s02: automatically measuring to obtain salinity information and water volume information in the existing cylinder body 01;

s03: according to the target value, automatically acquiring the volume of water required in the cylinder 01, corresponding to the amount of the added seawater with the salinity information to be diluted, and adding the amount of the seawater with the salinity information to be diluted when the total amount of water in the cylinder 01 is less than the volume X3 of the cylinder 01; simultaneously, automatically acquiring the adjustment quantity of the volume of the water in the cylinder body 01, wherein the adjustment quantity comprises an increase quantity or a decrease quantity;

s04: obtaining adjustment information;

s05: adjusting the original water amount in the cylinder body 01;

s06: then obtaining the volume of the seawater volume of the salinity information to be diluted which needs to be increased;

s07: automatically acquiring the water discharge amount of a water outlet pipe in unit time;

s08: dividing the volume of the seawater by the water discharge amount in unit time to obtain water discharge time;

the comprehensive analysis unit is used for transmitting the water discharging time to the processor, the processor is used for driving the control valve control unit to open the water discharging time corresponding to the valve to discharge water, and the water discharging time is controlled in a centralized mode through the network port, so that the operation cost of manually managing the equipment is reduced, a single-machine control panel is reduced, manual management is not needed, and the operation cost of customers is reduced;

the processor is used for transmitting the water discharging time to the display unit for real-time display.

As shown in fig. 1 and 13-19, the extension culture system is controlled by combining an intelligent computer version with a network port, and a traditional manual valve is replaced by an electromagnetic valve, so that the problems that a plurality of equipment valves are provided, the functions of the valves are not clear by operators, and misoperation is easy to occur are avoided; the closed filter barrel is used for replacing a traditional box-type filter barrel, manual operation is reduced, and the phenomenon that products are not filtered in place due to the fact that filter materials are not placed and reduced after manual operation is avoided, as shown in fig. 1, a water supplementing pipe at the top of a cylinder body is connected with a first water outlet pipe, and a seawater supplementing valve P2 is installed on the water supplementing pipe; a water replenishing pipe on the water pump is connected with the first water inlet pipe, and a seawater replenishing valve P1 is arranged on the water replenishing pipe; the device has the functions of automatically adding water and replenishing water, and also has the functions of automatically judging the salinity of the seawater and replenishing the seawater.

As shown in fig. 13, the tank body 01 comprises three layers of fish tanks, a fish scale collector 03 is installed at the bottom of each layer of fish tank, the oxygen increasing air pump 016 is respectively connected with the three layers of fish tanks through three oxygen supplying pipes 020, and the three oxygen supplying pipes 020 are respectively provided with an oxygen control valve Q1071, an oxygen control valve Q2072 and an oxygen control valve Q3073, so that oxygen in a water body can be increased conveniently, and the survival rate of aquatic products can be guaranteed.

As shown in fig. 13-16, the outlets of the fish scale collectors 03 are connected with a drain pipe 022, and the drain pipe 022 of the fish scale collector 03 positioned at the lowest position is connected to the bottom of a sedimentation sterilization strainer 04; the drain pipes 022 on the two fish scale collectors 03 located above are connected to the drain pipe 022 at the outlet of the sedimentation sterilization coarse filter 04 after being gathered, the drain pipes 022 on the two fish scale collectors 03 located above are respectively provided with a drain electric valve B2082 and a drain electric valve B3083 (as shown in fig. 13), the gathering point of the two drain pipes 022 is located behind the drain electric valve B2082 and the drain electric valve B3083, the drain electric valve B1081 and the drain electric valve B5085 are installed on the drain pipe 022 at the outlet of the sterilization coarse filter 04, and the drain pipes 022 on the two fish scale collectors 03 located above are connected to the drain electric valve B1081 and the drain pipe 022 between the drain electric valves B5085 after being gathered (as shown in fig. 13).

As shown in fig. 13, 15 and 18, a positioning barrel 018 is further installed on one side of the cylinder 01, and the positioning barrel 018 is connected with a protein separator 013 through a pipeline; the protein separator 013 is connected to a vesicle separator 014 via tubing; the protein separator 013 is also connected with a refrigerator 017 through a pipeline, and a jet device 015 is installed on the pipeline; the refrigerator 017 is connected to a water pump 012 through a pipe, and water can be purified by the protein separator 013 through the protein separator 013.

As shown in fig. 13, a vertically arranged germicidal lamp 0401 is installed in the sedimentation sterilization coarse filter 04, a movable sleeve is arranged at the bottom of the germicidal lamp 0401, a dirt blocking guide vane 0402 is installed on the periphery of the movable sleeve, the liquid treated by the sedimentation sterilization coarse filter 04 flows into a transparent filter 05 through a pipeline (as shown in fig. 13, the liquid enters through the upper part of the transparent filter 05), a drain pipe 022 at the outlet of the sedimentation sterilization coarse filter 04 is connected into the transparent filter 05 through a pipeline, a drain electric valve B4084 is installed on the pipeline, the liquid treated by the transparent filter 05 flows into a filter barrel group through a pipeline, a closed filter barrel 06 is used for replacing a traditional box-type filter barrel, the manual operation is reduced, and the phenomenon that the product is not filtered in place due to the fact that filter materials are not placed and restored after the manual operation; the filter vat set is connected with the refrigerator 017 and the water pump 012 respectively through a drain pipe 021, an operation control valve A3093 is installed on the drain pipe 021 of the filter vat set (as shown in the lower position of the filter vat in fig. 13) connected with the water pump 012, a check valve 011 is installed on the drain pipe 021 of the filter vat set connected with the refrigerator 017, the filtering and circulating system of the device adopts the vacuum pumping circulation principle, the problem of water shortage of the water pump is solved, and the device ensures that all water is completely filtered.

As shown in fig. 13 to 16, a filter housing 02 is installed above the fish scale collector 03 and located in the cylinder 01, and impurities, fish scales, and the like in the cylinder 01 are primarily filtered through the filter housing 02 and the fish scale collector 03. The device utilizes the physical principle, is additionally provided with the preposed fish scale sundries filter, utilizes the slowing-down water flow to make the heavy object sink, stays in the preposed filter and does not participate in the filtration, and ensures that the filter material is not polluted by sundries.

As shown in fig. 13 and 17, a horizontal exhaust top valve 0501 is installed above the transparent filter 05, a floating fine particle filter (transparent filter 05) is installed, and a horizontal exhaust top valve 0501 is installed, so that the horizontal exhaust top valve 0501 is pushed open by horizontal pressure when water is added, and the exhaust port is pressed by a water pump 012 when water is absorbed, so that the filtration is performed in a vacuum state.

As shown in fig. 15, a positioning switch 01801 is installed on a positioning barrel 018, as shown in fig. 13-17, the top of a cylinder body 01 and a water replenishing pipe 023 are connected to a water pump 012, wherein, as shown in fig. 13, the top of the cylinder body 01 is also connected with a water inlet pipe, a water adding electromagnetic valve 019 is installed on the water inlet pipe, as a pilot run electric valve, water is injected into a system when the pilot run electric valve operates at every time, the smoothness of the system can be detected, the water replenishing pipe 023, an oxygen replenishing pipe 020, a drain pipe 021 and a drain pipe 022 are all installed with electromagnetic valves, the traditional manual valve is replaced by the electric valve, the problems that the number of equipment valves is large, operators cannot clearly see the functions of the.

As shown in fig. 13 and 19, the filter barrel set comprises two filter barrels 06, the inside of the filter barrel 06 is filled with filter material, and check valves 011 are respectively installed on a drain pipe 022 connected with the transparent filter 05 and a drain pipe 021 connected with the refrigerator 017 of the filter barrel set; the upper part of one of the filter barrels 06 is connected with the outlet of the transparent filter 05 through a drain pipe 022, and the bottom of the filter barrel 06 is connected with the upper part of the other filter barrel 06 through a drain pipe 021; the upper part of the filter barrel 06 connected with the transparent filter 05 is also connected with the water pump 012 through a water supplementing pipe 023, and the water supplementing pipe 023 is provided with an operation control valve A4094; the water pump 012 and the refrigerator 017 are connected through a pipeline, and an operation control valve A2092 is installed on the pipeline; the lower part of the cylinder 01 is connected to a water pump 012 via a pipe, and an operation control valve a1091 is attached to the pipe.

An artificial intelligence interconnection seafood pool operation system for aquaculture equipment utilizes an electric valve to replace a traditional manual valve, avoids the problems that the equipment has more valves, the functions of the valves are not obscured by operators, and misoperation is easy; the closed filter barrel is used for replacing a traditional box-type filter barrel, so that manual operation is reduced, and the phenomenon that the product is not filtered in place due to the fact that filter materials are not placed and reduced after manual operation is avoided; the filtering and circulating system adopts a vacuum pumping and circulating principle, is additionally provided with a transparent filter and a horizontal exhaust top valve, utilizes horizontal pressure when adding water to jack the valve for exhausting, and compresses an exhaust port when a water pump absorbs water to enable the filtering to form vacuum state operation, so that the problem of water shortage of the water pump is solved, and the equipment ensures that all water is completely filtered; by utilizing the physical principle, a preposed fish scale sundries filter is additionally arranged, heavy objects sink by slowing down water flow, and the heavy objects are left in the preposed filter and do not participate in filtering, so that the filter material is ensured not to be polluted by sundries; the water is stored in the storage chamber, the salt storage chamber is communicated with the storage chamber through a second water inlet pipe, the mixing chamber is communicated with the storage chamber through a second water inlet pipe, and the mixing chamber is communicated with the salt storage chamber through a third water inlet pipe; the distributor is communicated with the mixing chamber through a water inlet pipe IV; the distributor is provided with a plurality of water outlet interfaces, a first partition plate assembly and a second partition plate assembly are sequentially arranged in the salt storage chamber from bottom to top, and an alarm probe is further arranged in the salt storage chamber and is formed by connecting a multi-port seawater proportioning system and a plurality of extension devices in parallel, so that the problems of seawater proportioning and seawater supplementing difficulty in the industry are solved.

In the description herein, references to the description of "one embodiment," "an example," "a specific example" or the like are intended to mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The preferred embodiments of the invention disclosed above are intended to be illustrative only. The preferred embodiments are not intended to be exhaustive or to limit the invention to the precise embodiments disclosed. Obviously, many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles of the invention and the practical application, to thereby enable others skilled in the art to best utilize the invention. The invention is limited only by the claims and their full scope and equivalents.

Claims (10)

1. An artificial intelligence interconnection seafood pool operation system for aquaculture equipment is characterized by comprising a multi-cylinder interconnection seawater proportioning system and an extension aquaculture system connected with the multi-cylinder interconnection seawater proportioning system;

the multi-cylinder interconnected seawater proportioning system comprises:

a storage chamber (2);

the salt storage chamber (7) is communicated with the accommodating chamber (2) through a second water inlet pipe (5);

the mixing chamber (13) is communicated with the accommodating chamber (2) through a second water inlet pipe (5), and the mixing chamber (13) is communicated with the salt storage chamber (7) through a third water inlet pipe (19);

the distributor (10), the said distributor (10) communicates with mixing chamber (13) through the inlet pipe four (20);

the storage chamber (2) is provided with a plurality of water inlet interfaces (201), and the water inlet interfaces (201) are connected with the first water inlet pipe (1); the distributor (10) is provided with a plurality of water outlet interfaces (1001), and the water outlet interfaces (1001) are connected with the first water outlet pipe (11);

a first partition plate assembly (6) and a second partition plate assembly (8) are sequentially arranged in the salt storage chamber (7) from bottom to top, and an alarm probe (12) is also arranged in the salt storage chamber (7);

a mixer (14) is arranged in the mixing chamber (13), and the mixer (14) comprises turbine blades (15) and impeller blades (16);

a first water pump (3) and an electromagnetic valve (4) are installed on the second water inlet pipe (5);

the extension farming systems include: a cylinder body (01) and an oxygen increasing air pump (016);

the tank body (01) comprises three layers of fish tanks, a fish scale collector (03) is arranged at the bottom of each layer of fish tank, and the oxygen increasing air pump (016) is respectively connected with the three layers of fish tanks through three oxygen supplying pipes (020);

the outlets of the scale collectors (03) are connected with a drain pipe (022), and the drain pipe (022) on the scale collector (03) positioned at the lowest part is connected to the bottom of a sedimentation sterilization coarse filter (04);

the drain pipes (022) on the two fish scale collectors (03) positioned above are gathered and then connected to the drain pipe (022) at the outlet of the sedimentation sterilization coarse filter (04);

one side of the cylinder body (01) is also provided with a positioning barrel (018), and the positioning barrel (018) is connected with a protein separator (013) through a pipeline;

the protein separator (013) is connected with a water bubble separator (014) through a pipeline;

the protein separator (013) is also connected with a refrigerator (017) through a pipeline, and the pipeline is provided with a jet device (015);

the refrigerator (017) is connected with a water pump (012) through a pipeline;

the liquid treated by the precipitation sterilization coarse filter (04) flows into a transparent filter (05) through a pipeline, and the liquid treated by the transparent filter (05) flows into a filter barrel group through a pipeline;

the filter barrel group is respectively connected with the refrigerator (017) and the water pump (012) through a drain pipe (021);

a water replenishing pipe (023) is connected to the uppermost part of the cylinder body (01) and the water pump (012); the water replenishing pipe (023) at the uppermost part of the cylinder body (01) is connected with the first water outlet pipe (11), and a seawater replenishing valve P2(0102) is installed on the water replenishing pipe (023); a water replenishing pipe (023) on the water pump (012) is connected with the first inlet pipe (1), and a seawater replenishing valve P1(0101) is installed on the water replenishing pipe (023);

electrically operated valves are arranged on the water replenishing pipe (023), the oxygen replenishing pipe (020), the drain pipe (021) and the blow-off pipe (022).

2. The artificial intelligence interconnected seafood pool operating system for aquaculture equipment of claim 1, wherein each said water outlet (1001) is connected to a cylinder (01).

3. The artificial intelligence interconnected seafood pool operating system for the aquaculture equipment as claimed in claim 1, wherein the first partition plate assembly (6) comprises a filter plate (601) installed in a salt storage chamber (7), the filter plate (601) is divided into a plurality of filter zones by barrier strips (6012), each filter zone is provided with a filter screen (6011), and the mesh number of the plurality of filter screens (6011) is different.

4. The artificial intelligence interconnected seafood pool operating system for the aquaculture apparatus of claim 3, wherein the first partition plate assembly (6) further comprises a baffle (602) corresponding to each filtering area, and each baffle (602) is mounted on the corresponding baffle strip (6012) through a telescopic piece (604); the side surface of the baffle (602) is also provided with a guide block (603), and the inner wall of the salt storage chamber (7) is provided with a guide groove corresponding to the guide block (603); and rubber rings (6021) corresponding to each filtering area are also arranged on the baffle (602).

5. The artificial intelligence interconnected seafood pool operating system for the aquaculture device as claimed in claim 1, wherein a vertically arranged germicidal lamp (0401) is installed in the sedimentation sterilization coarse filter (04), a movable sleeve is arranged at the bottom of the germicidal lamp (0401), and a dirt blocking guide vane (0402) is installed on the periphery of the movable sleeve.

6. An artificial intelligence interconnected seafood pool operating system for aquaculture apparatus as claimed in claim 1 wherein a horizontal exhaust top valve (0501) is mounted above the transparent filter (05).

7. The artificial intelligence interconnected seafood pool operating system for aquaculture equipment of claim 1, wherein:

the filter vat set comprises two filter vats (06);

the upper part of one of the filter barrels (06) is connected with the outlet of the transparent filter (05) through a drain pipe (022), and the bottom of the filter barrel (06) is connected with the upper part of the other filter barrel (06) through a drain pipe (021).

8. The interconnected seafood pond operating system of artificial intelligence for aquaculture equipment of claim 7, characterized in that, the upper portion of filter vat (06) that is connected with transparent filter (05) still is connected with water pump (012) through moisturizing pipe (023), and the inside of filter vat (06) is filled with the filter media.

9. The interconnected seafood pool operating system of artificial intelligence for aquaculture equipment of claim 8, wherein the filter vat set is equipped with check valves (011) on the drain pipe (022) connected to the transparent filter (05) and the drain pipe (021) connected to the refrigerator (017).

10. The artificial intelligence interconnected seafood pool operating system for aquaculture equipment of claim 1, wherein:

the salinity monitoring system also comprises a salinity detection unit, a comprehensive analysis unit, a self-identification unit, a salinity planning unit, a volume determination unit, a processor, a display unit and a valve control unit;

the salinity detection unit is arranged in the distributor (10) and used for measuring salinity information in the distributor (10) in real time and marking the salinity information as salinity information to be diluted, the salinity detection unit is used for transmitting the salinity information to be diluted to the comprehensive analysis unit, and the comprehensive analysis unit receives the salinity information to be diluted transmitted by the salinity detection unit;

the self-identification unit is arranged in the corresponding cylinder body (01) and used for identifying marine products in the cylinder body (01) and marking the obtained marine products as audience object information, the self-identification unit is used for transmitting the audience object information to the salinity planning unit, the salinity planning unit receives the audience object information transmitted by the self-identification unit and performs self-planning analysis, and the specific analysis steps are as follows:

the method comprises the following steps: firstly, acquiring all audience object information, and marking the audience object information as Zi, i-1.. n;

step two: acquiring the proper salinity ranges of all the audience object information Zi, and marking the salinity ranges as Fi, i-1.. n;

step three: then, acquiring the cross range of all the Fi, and marking the cross range as a proper salinity area when all the Fi has the cross range; automatically taking the median value of the suitable salinity area, and marking the median value as target salinity regulation;

step four: if all the Fi do not have the same intersection range, performing circle division processing, specifically processing steps of:

s1: the method comprises the steps that the Fi with the common range is divided into the same range group, and the Fi is divided under the condition that the number of the range groups is the minimum;

s2: all range groups were obtained and labeled Wj, j 1.. m;

s3: automatically obtaining a median value for all range groups, which is labeled Wzj, j 1.. m; wzj correspond to Wj one-to-one;

s4: then, calculating the average value of all the median values, and marking the value as a target value;

s5: subtracting the target value from Wzj, and if the obtained difference value exceeds X1 and X1 is a user preset numerical value, correspondingly deleting Wzj;

s6: carrying out average value solving on the residual Wzj, and marking the obtained average value as a target value;

s7: automatically searching for the mortality rate of all seafood products in the cylinder (01) when the target value is reached, and marking the seafood products with the mortality rate exceeding X2 as objects to be removed; x2 is a preset value;

step five: transmitting the removal object and the target value to the comprehensive analysis unit;

the comprehensive analysis unit receives the removal object and the target value transmitted by the salinity planning unit; the volume measuring unit is used for measuring the volume of the cylinder body (01) and transmitting the volume to the comprehensive analysis unit;

the comprehensive analysis unit is used for carrying out valve control time period analysis by combining the volume of the cylinder body (01), a target value and information of salinity to be diluted, and the specific analysis steps are as follows:

s01: obtaining a target value, information of salinity to be diluted and the volume of the cylinder body (01);

s02: the salinity information and the water volume information in the existing cylinder body (01) are obtained through automatic measurement;

s03: according to the target value, automatically acquiring the volume of water needed in the cylinder body (01), corresponding to the amount of seawater added with the salinity information to be diluted, and adding the amount of seawater with the salinity information to be diluted when the total amount of water in the cylinder body (01) is less than the volume X3 of the cylinder body (01); automatically acquiring the adjustment amount of the volume of water in the cylinder body (01), wherein the adjustment amount comprises an increase amount or a decrease amount;

s04: obtaining adjustment information;

s05: adjusting the original water amount in the cylinder body (01);

s06: then obtaining the volume of the seawater volume of the salinity information to be diluted which needs to be increased;

s07: automatically acquiring the water discharge amount of a water outlet pipe in unit time;

s08: dividing the volume of the seawater by the water discharge amount in unit time to obtain water discharge time;

the comprehensive analysis unit is used for transmitting the water discharging time to the processor, and the processor is used for driving the control valve control unit to open the water discharging time corresponding to the valve for water discharging;

the processor is used for transmitting the water discharging time to the display unit for real-time display.

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