CN111635063B - Breeding sewage treatment equipment and method based on artificial intelligence - Google Patents

Abstract

The invention discloses artificial intelligence based breeding sewage treatment equipment and method, belonging to the technical field of sewage treatment; the processing system comprises an equipment box body, a water inlet pipe, a power supply cabinet, a trough plate and a distribution box; the equipment box body is formed by splicing metal plates into a rectangular box body, an inner cavity is formed in the equipment box body in a slotted mode, four corners of the bottom end of the equipment box body are respectively welded with a foot stand, an operation table is welded on the right side of the equipment box body, and the operation table is formed by splicing channel steel pieces; the frid sets up in the inner chamber upper end, frid and equipment box inner wall joint, equipment itself utilizes and comes the real-time control equipment pipeline based on artificial intelligence control system, the process is filtered in the water purification, and utilize and nitrify, the denitrification gets rid of the material such as ammonia nitrogen that contains in breeding the sewage, and carry out the aeration to sewage in step, increase aquatic oxygen content when accelerating sewage degradation reaction rate, the problem of breeding sewage that has faced at present can't carry out high-efficient processing, it is with high costs to handle and breed the water, the suitability is lower is solved.

Description

Breeding sewage treatment equipment and method based on artificial intelligence

Technical Field

The invention relates to the technical field of sewage treatment, in particular to cultivation sewage treatment equipment and a cultivation sewage treatment method based on artificial intelligence.

Background

In the aquaculture industry, the water quality of aquaculture water is the most important part for growth of fishes, the water source of the aquaculture water can be used as the aquaculture water only through multi-stage and step treatment, meanwhile, the timeliness of the aquaculture water is directly determined by the aquaculture scale, a large amount of fish excrement and ammonia nitrogen generated by excrement fermentation and the like are left in aquaculture sewage, the oxygen content in the aquaculture water is inhibited while the water quality is influenced, the recycling is not achieved, the aquaculture cost is increased, and meanwhile, the waste of water resources is caused.

Based on the problems, the artificial intelligence treatment equipment suitable for treating aquaculture sewage in the current era needs to be researched, the aquaculture sewage produced in the current era cannot be recycled, the treatment efficiency of the current treatment mode is low, the effect taking process is slow, the discharge of the aquaculture sewage is difficult to deal with, the treatment mode needs to be attended by professionals, the cost is high, the applicability is low, and the healthy development of aquaculture is limited to a certain extent.

Disclosure of Invention

Technical problem to be solved

The invention aims to solve the problems and provide artificial intelligence-based aquaculture sewage treatment equipment and method, wherein the equipment utilizes an artificial intelligence-based control system to control an equipment pipeline and a purified water filtering process in real time, utilizes nitration and denitrification reactions to remove substances such as ammonia nitrogen and the like contained in aquaculture sewage, synchronously aerates the sewage, accelerates the degradation reaction rate of the sewage and simultaneously increases the oxygen content in the water, and solves the problems that the existing aquaculture sewage cannot be efficiently treated, the treatment cost is high, and the applicability is low.

In order to achieve the purpose, the technical scheme adopted by the invention is as follows: an artificial intelligence-based aquaculture sewage treatment device, comprising:

the processing system comprises an equipment box body, a water inlet pipe, a power supply cabinet, a trough plate and a distribution box; the equipment box body is formed by splicing metal plates into a rectangular box body, an inner cavity is formed in the equipment box body in a slotted mode, four corners of the bottom end of the equipment box body are welded with a foot stand respectively, an operation table is welded on the right side of the equipment box body, and the operation table is formed by splicing channel steel pieces; the groove plate is arranged at the upper end of the inner cavity and is clamped with the inner wall of the equipment box body, and the groove plate separates the space at the upper end of the inner cavity and forms a sewage tank; the water inlet pipe is arranged at the upper left end of the equipment box body, the water inlet pipe is fixedly connected with the side wall of the equipment box body, and a pipe orifice at one end of the water inlet pipe faces the sewage tank; the power cabinet is arranged at the lower end of the front side of the equipment box body, the power cabinet is embedded in the equipment box body, and a storage battery is embedded in the power cabinet; the distribution box is embedded in the inner cavity, the distribution box is fixed on the front side of the inner cavity and is tightly attached to the power cabinet, the distribution box comprises a return pipe, a check valve, a lower box and an upper box, the upper box and the lower box are symmetrically embedded in the upper end and the lower end of the distribution box, the lower end of the lower box is provided with an L-shaped pipeline in a penetrating manner, the joint of the lower box and the L-shaped pipeline is sleeved with an electromagnetic valve, the upper end of the upper box is provided with a T-shaped pipe head, the T-shaped pipe head penetrates through a groove plate, the sewage tank is communicated with the upper box through the T-shaped pipe head, the return pipe and the check valve are provided with two pairs in total, the return pipe is a U-shaped pipeline, the check valve is arranged in the middle of the return pipe, the return pipe is symmetrically arranged at the left end and the right end of the front side of the equipment box body, the upper end and the lower end of the return pipe penetrate between the equipment box body and the distribution box, the upper end and the lower end of the return pipe are respectively spliced with the upper box and the lower box through the return pipe;

the water purification system comprises a filter pipe, a water storage barrel and a reaction barrel; the reaction barrel is embedded in the middle of an inner cavity, an air storage cavity and a reaction cavity which are mutually independent are formed at the upper end and the lower end of the inner side of the reaction barrel, a narrow-mouth channel is formed between the air storage cavity and the reaction cavity, an anaerobic layer is filled in the narrow-mouth channel, a pair of valve port pipes are inserted at the lower end of the reaction barrel and communicated with the reaction cavity, a sewage hose is arranged on the left side of each valve port pipe in a penetrating manner, the other end of each sewage hose is communicated with an L-shaped pipeline in a lower box, each sewage hose is communicated with the reaction cavity through each valve port pipe, a switching pipe is arranged at the lower end of each valve port pipe in a penetrating manner, a pipeline is inserted at the right side of each valve port pipe in a penetrating manner, the pipeline extends towards the right side and penetrates through an equipment box body, a fan is fixed at the lower end of the right side of the equipment box body, and the fan is communicated with the tail end of the pipeline; the four filter tubes are arranged on the outer side of the upper end of the sewage tank at equal intervals in the transverse direction, one end of each filter tube penetrates through the tank plate and then is communicated with the valve port pipe, the other end of the filter material pipe is provided with a material barrel in a penetrating way, the material barrel is fixedly connected with the equipment box body, and a biological filter material is added in the material barrel; the two water storage barrels are arranged on the right side of the inner cavity in an embedded mode, the water storage barrels are located at the lower end of the pipeline on the right side of the valve port pipe, the water storage barrels are communicated with one another through hoses, a water outlet pipe is arranged at the right end of each water storage barrel in a penetrating mode, and the water outlet pipe penetrates through the back face of the equipment box body; the filter pipe is arranged in the middle of the right side of the equipment box body, the filter pipe is embedded with the equipment box body, the left end and the right end of the filter pipe are respectively provided with a connecting pipe and a water drain pipe in a penetrating way, one end of the connecting pipe penetrates through the equipment box body and is communicated with the adapter pipe, one end of the water drain pipe penetrates through the equipment box body and is communicated with the left end of the water storage barrel, a liquid cavity is formed in the filter pipe, a plug pipe head and a filter screen are embedded in the liquid cavity, the plug pipe head is embedded in the connecting pipe, a spiral pipe is arranged between the plug pipe head and the liquid cavity in a penetrating way, the pipe wall of the spiral pipe is in a spiral shape of the screw hole, the filter screen is provided with ten pieces in total, the filter screens are transversely distributed in the liquid cavity at equal intervals, and the filter screens are clamped with the liquid cavity;

the control system comprises a flow box, a control box and a cabinet; the flow box is arranged at the upper end of the operating platform and is embedded with the equipment box body, the flow box is composed of a plurality of groups of water flow meters, and the input end of the flow box is electrically connected with the output end of the storage battery; the cabinet is embedded in the inner cavity and is embedded at the front end of the distribution box, the cabinet is formed by splicing metal frame plates, a host and a server are arranged in the cabinet, the host is fixed at the upper end of the server, the host and the server are both clamped with the inner wall of the cabinet, the host is a processing system based on an artificial intelligent operating system, the operating system in the host comprises a flow metering module and a valve port channel control module controlled by a PLC system, the flow metering module comprises a flow valve and a flow meter which are contained in a water purifying system, the output end of the flow metering module is electrically connected with the input end of the flow box, the valve port channel control module comprises electromagnetic valves distributed at each valve port and each pipe orifice in the water purifying system, the server comprises a time servo control module, the time servo control module in the server is electrically connected with a fan and an air pump, and the output end of the server is electrically connected with the input end of the host; the control box is arranged at the left end of the right side wall of the equipment box body, the control box is embedded with the equipment box body, a power button and an indicator light are distributed on the surface of the control box, the inner side of the control box penetrates through the middle of the front side of the cabinet, a connection port plate is fixed on the inner side of the control box, the connection port plate is composed of a plurality of data interfaces and cable interfaces, and the connection port plate is electrically connected with the host through cables;

according to the specific scheme, the surface of the T-shaped pipe head at the upper end of the upper box is in a rectangular slotted hole shape, and flowmeters are arranged on the outer sides of the upper box and the lower box in a penetrating mode.

In a specific scheme, the wall of a throat pipe in the anaerobic layer is spiral, and the anaerobic layer is formed by denitrifying biological filler.

In a specific scheme, the adding ratio of the biological filter material to the anaerobic layer biological filler in the charging barrel is 1: 2-1.

In a specific scheme, the valve port in the valve port pipe and the pipe orifice at the joint of the pipe are both solenoid valve ports.

According to the specific scheme, a sealing ring is sleeved at the joint of the water drain pipe and the water storage barrel, the sealing ring body is in interference connection with the barrel wall of the water storage barrel, and a flowmeter is arranged at the upper end of the sealing ring in a penetrating mode.

According to the specific scheme, an air pump is fixed on the left side of the equipment box body and comprises an air charging pipeline, one end of the air charging pipeline is communicated with the air pump, the other end of the air charging pipeline penetrates through the equipment box body and then is inserted into the lower end of the back face of the reaction barrel, and the air pump is communicated with the reaction cavity through the air charging pipeline.

In a specific scheme, the mesh specification of the filter screen is selected according to the type specification of the selected biological filter material and biological filler.

The invention further provides a fire risk assessment method based on the lithium battery, which comprises the following steps:

and (3) an installation stage: the device box body is arranged in a water source area of a culture place in a transportation mode and the like, a culture sewage discharge pipeline is connected with a water inlet pipe, a water source pipeline is connected with a water outlet pipe, a water pump is arranged at the joint, and an operator turns on the device through a switch of a control box after a power supply cabinet is connected with a power supply;

and (3) a treatment stage: the discharged sewage is discharged into a sewage tank through a water inlet pipe, and pipeline channels such as a valve port and the like are controlled through a control system host, so that the sewage sequentially passes through equipment pipelines along the sequence from an upper tank, a return pipe, a lower tank, a sewage hose, a valve port pipe, a reaction barrel and a switching pipe to a water storage barrel;

a water purification stage; separating impurities such as fish corpses and the like in sewage through an upper box and a lower box, then carrying out nitration reaction in a reaction chamber of a reaction barrel to remove ammonia nitrogen in the sewage to produce nitric acid and carry out denitrification reaction to degrade the nitric acid in the water, carrying out synchronous aeration on a water body in the process, and finally filtering the impurities such as residual filter materials, fillers and the like in the water along with a filtering pipe;

a circulation stage: the water after filtering is stored by the water storage barrel, and the staff utilizes the water pump to suck the water in the water storage barrel for subsequent water culture so as to meet the requirement of aquaculture water.

Due to the adoption of the technical scheme, the invention has the following beneficial effects:

1. the artificial intelligence-based aquaculture sewage treatment equipment and the artificial intelligence-based aquaculture sewage treatment method synchronously carry out nitrification, denitrification and aeration treatment on aquaculture sewage, and successively carry out vortex-shaped mixed flow and filtration on a water body, wherein degradation reaction and aeration are carried out simultaneously in the filtration treatment process, so that on one hand, the mixed reaction of a filter material and the aquaculture sewage is accelerated by utilizing the backflushing of gas to the water body, and on the other hand, the oxygen content in the aquaculture sewage is improved by utilizing the rushing of the gas, so that the subsequent aquaculture sewage treatment is facilitated, and meanwhile, the flocculation of impurities in the aquaculture sewage is avoided.

2. According to the artificial intelligence based aquaculture sewage treatment equipment and method, the control of the process of the filtration stage is completed based on the artificial intelligence control system, the filling ratio is controlled by using the filling time of the valve, the valve port channel pipeline, the filter material and the gas, the stable operation of sewage treatment is ensured, and the problems of high cost and low applicability caused by manual supervision and treatment of traditional professionals are solved.

3. According to the artificial intelligence-based aquaculture sewage treatment equipment and the artificial intelligence-based aquaculture sewage treatment method, the treatment equipment structure is subjected to modular integrated packaging through the equipment box body, the distribution box, the cabinet and the like, so that the treatment equipment is convenient to install and transport, and meanwhile, the applicability of the treatment equipment is further improved.

4. According to the artificial intelligence-based aquaculture sewage treatment equipment and method, the equipment can efficiently flush the internal pipeline through the air pump pipeline, the maintenance is simple and convenient, the operation cost is reduced to a certain extent, and the applicability of the equipment is improved.

Drawings

Fig. 1 is a schematic view of the overall structure of the present invention.

FIG. 2 is a schematic view of the overall construction of the filter cartridge of the present invention.

FIG. 3 is a schematic view of the internal structure of the filter tube of the present invention.

FIG. 4 is a partial structure diagram of the box body of the equipment.

Fig. 5 is a schematic structural diagram of the cabinet of the present invention.

FIG. 6 is a side view of the internal structure of the case of the apparatus of the present invention.

FIG. 7 is a front view of the internal structure of the case of the apparatus of the present invention.

In the attached drawing, 1-equipment box body, 2-sewage tank, 3-water inlet pipe, 4-filter pipe, 5-flow tank, 6-operation table, 7-filter pipe, 8-power cabinet, 9-control box, 10-foot stand, 11-return pipe, 12-check valve, 13-stopper head, 14-connecting pipe, 15-drain pipe, 16-sealing ring, 17-spiral pipe, 18-liquid cavity, 19-filter screen, 20-tank plate, 21-storage battery, 22-flow distribution box, 23-inner cavity, 24-cabinet, 25-host computer, 26-connecting port plate, 27-servo, 28-material cylinder, 29-blower, 30-water outlet pipe, 31-water storage barrel, 32-flow valve, 33-adapter pipe, 34-valve port pipe, 35-sewage hose, 36-lower tank, 37-upper tank, 38-reaction barrel, 39-air pump, 40-reaction cavity, 41-anaerobic layer and 42-air storage cavity.

Detailed Description

The following detailed description of the invention is provided in connection with the accompanying drawings

The invention relates to artificial intelligence-based cultivation sewage treatment equipment and a method.

As shown in fig. 1-7, the treatment system comprises an equipment box body 1, a water inlet pipe 3, a power supply cabinet 8, a trough plate 20 and a distribution box 22; the equipment box body 1 is formed by splicing metal plates into a rectangular box body, an inner cavity 23 is formed in a groove in the equipment box body 1, four corners of the bottom end of the equipment box body 1 are respectively welded with a foot stand 10, the right side of the equipment box body 1 is welded with an operating platform 6, and the operating platform 6 is formed by splicing channel steel pieces; the groove plate 20 is arranged at the upper end of the inner cavity 23, the groove plate 20 is clamped with the inner wall of the equipment box body 1, and the groove plate 20 separates the space at the upper end of the inner cavity 23 and forms a sewage tank 2; the water inlet pipe 3 is arranged at the upper left end of the equipment box body 1, the water inlet pipe 3 is fixedly connected with the side wall of the equipment box body 1, and a pipe orifice at one end of the water inlet pipe 3 faces the sewage tank 2; the power cabinet 8 is arranged at the lower end of the front side of the equipment box body 1, the power cabinet 8 is embedded in the equipment box body 1, and a storage battery 21 is embedded in the power cabinet 8; the flow distribution box 22 is embedded in the inner cavity 23, the flow distribution box 22 is fixed on the front surface of the inner cavity 23, the flow distribution box 22 is tightly attached to the power cabinet 8, the flow distribution box 22 comprises a return pipe 11, a check valve 12, a lower box 36 and an upper box 37, the upper box 37 and the lower box 36 are symmetrically embedded in the upper end and the lower end of the flow distribution box 22, the lower end of the lower box 36 is provided with an L-shaped pipeline in a penetrating manner, a solenoid valve is sleeved at the joint of the lower box 36 and the L-shaped pipeline, a T-shaped pipe head is arranged on an opening at the upper end of the upper box 37 and penetrates through the trough plate 20, the sewage trough 2 is communicated with the upper box 37 through the T-shaped pipe head, the return pipe 11 and the check valve 12 are provided with two pairs, the return pipe 11 is a U-shaped pipeline, the check valve 12 is arranged in the middle of the return pipe 11, the return pipe 11 is symmetrically arranged at the left end and the right end of the front surface of the equipment box 1, the upper end and the lower end of the return pipe 11 penetrate through the equipment box 1 and the flow distribution box 22, the upper end and the lower end of the return pipe 11, the upper end and the lower end of the return pipe 11 are respectively inserted in the upper box 37 and the lower box 36, and the upper box 37, and the return pipe 37 are respectively inserted with the lower box 36, and the return pipe 37; after the pipe orifice at one end of the water inlet pipe 3 is connected with the aquaculture drainage pipeline, sewage is discharged into the sewage tank 2 through the water inlet pipe 3 and then converged into the upper box 37 along the T-shaped pipe head, and the sewage is discharged along with the L-shaped pipeline at the lower end of the lower box 36 after passing through the return pipe 11 and the lower box 36, wherein the power cabinet 8 serves as a power supply of the equipment and is used for enabling control system components such as an electromagnetic valve and the like in the equipment box body 1 to operate.

The surface of the T-shaped pipe head at the upper end of the upper box 37 is in a rectangular groove hole shape, flowmeters are arranged on the outer sides of the upper box 37 and the lower box 36 in a penetrating mode, and when sewage is discharged into the upper box 37 and the lower box 36 from the T-shaped pipe head, large particle impurities contained in the sewage are filtered by the T-shaped pipe head groove holes in advance.

As shown in fig. 1-7, the water purification system comprises a filter tube 4, a filter tube 7, a water storage barrel 31 and a reaction barrel 38; the reaction barrel 38 is embedded in the middle of the inner cavity 23, the upper end and the lower end of the inner side of the reaction barrel 38 are provided with an air storage cavity 42 and a reaction cavity 40 which are mutually independent, a narrow opening channel is formed between the air storage cavity 42 and the reaction cavity 40, an anaerobic layer 41 is filled in the narrow opening channel, the lower end of the reaction barrel 38 is connected with a pair of valve opening pipes 34 in an inserting manner, the valve opening pipes 34 are communicated with the reaction cavity 40, the left side of each valve opening pipe 34 is provided with a sewage hose 35 in a penetrating manner, the other end of each sewage hose 35 is communicated with an L-shaped pipeline in the lower box 36, each sewage hose 35 is communicated with the reaction cavity 40 through each valve opening pipe 34, the lower end of each valve opening pipe 34 is provided with a switching pipe 33 in a penetrating manner, the right side of each valve opening pipe 34 is connected with a pipeline in an inserting manner, the pipeline extends towards the right side and penetrates through the equipment box 1, the lower end of the right side of the equipment box 1 is fixedly provided with a fan 29, and the air opening of the fan is communicated with the tail end of the pipeline; the four filter material pipes 4 are arranged in the sewage tank 2, the filter material pipes 4 are transversely arranged at equal intervals outside the upper end of the sewage tank 2, one end of each filter material pipe 4 penetrates through the tank plate 20 and then is communicated with the valve port pipe 34 through a pipeline, the other end of each filter material pipe 4 is provided with a material barrel 28 in a penetrating manner, the material barrel 28 is fixedly connected with the equipment tank body 1, and biological filter materials are added in the material barrel 28; the number of the water storage barrels 31 is two, the water storage barrels 31 are embedded in the right side of the inner cavity 23, the water storage barrels 31 are located at the lower ends of pipelines on the right side of the valve port pipe 34, the water storage barrels 31 are communicated with one another through hoses, a water outlet pipe 30 is arranged at the right end of each water storage barrel 31 in a penetrating mode, and the water outlet pipe 30 penetrates through the back face of the equipment box body 1; the filtering pipe 7 is arranged in the middle of the right side of the equipment box body 1, the filtering pipe 7 is embedded with the equipment box body 1, the left end and the right end of the filtering pipe 7 are respectively provided with a connecting pipe 14 and a water drain pipe 15 in a penetrating way, one end of the connecting pipe 14 penetrates through the equipment box body 1 and is communicated with a transfer pipe 33, one end of the water drain pipe 15 penetrates through the equipment box body 1 and is communicated with the left end of the water storage barrel 31, a liquid cavity 18 is formed in the filtering pipe 7, a plug pipe head 13 and a filter screen 19 are embedded in the liquid cavity 18, the plug pipe head 13 is embedded in the connecting pipe 14, a spiral pipe 17 is arranged between the plug pipe head 13 and the liquid cavity 18 in a penetrating way, the pipe wall of the spiral pipe 17 is in a screw hole vortex shape, the filter screen 19 is provided with ten vortex sheets, the filter screen 19 is transversely and equidistantly distributed in the liquid cavity 18, and the filter screen 19 is clamped with the liquid cavity 18; after being discharged from an L-shaped pipe of a lower box 36, sewage flows into a left valve port pipe 34 along a sewage hose 35, a valve port between the valve port pipe 34 and an adapter pipe 33 is closed, the sewage flows into a reaction cavity 40 in a reaction barrel 38 along a pipeline of the valve port pipe 34, after a fan 29 at the other end operates, airflow of a right pipeline of the valve port pipe 34 is exhausted, when the air pressure in the pipeline is smaller than the air pressure in a charging barrel 28, a biological filter material is discharged into the right valve port pipe 34 along with the airflow and then flows into the reaction cavity 40, when the sewage fills the reaction cavity 40, the airflow carries the biological filter material along the lower end of the valve port pipe and rushes into the reaction cavity 40, the air breaks the flow and then is discharged into an air storage cavity 42 along a narrow-mouth channel and an anaerobic layer 41, the sewage is subjected to nitration reaction with the biological filter material in the reaction cavity 40, the fish feces and the ammonia gas in the sewage react with the biological filter material to generate nitric acid and nitrous acid, synchronously, and the airflow rushed in the process accelerates the contact of the biological filter material and the sewage, the air bubbles are flushed to improve the oxygen content in the sewage, when the flow of the biological filter material and the air reaches the threshold value of the air storage cavity 42, the fan 29 stops working, the air and the biological filter material are not filled into the reaction cavity 40 any more, the air and the material filled into the air storage cavity 42 are free to settle after being not influenced by the wind speed, the air and part of the biological filter material carry the filler material in the anaerobic layer 41 to carry out denitrification reaction with the sewage in the reaction cavity 40 to remove the substances such as ammonia nitrogen and the like in the sewage, after the valve port between the valve port pipe 34 and the adapter pipe 33 is opened, the water subjected to denitrification treatment is discharged along the adapter pipe 33 and then discharged into the filter pipe 7 along the adapter pipe 33 and the connecting pipe 14, and in the process of introducing the water into the filter pipe 7, the water flows into the liquid cavity 18 along the spiral pipe 17 in a vortex shape, and the residual salt materials and the biological filler in the water are filtered through the filter screen 19, filtering impurities, and finally discharging the filtered impurities into the water storage barrel 31 through the water discharge pipe 15 at the other end of the filtering pipe 7, wherein the water discharge pipe 30 can be connected with a pumping device to obtain the sewage after being treated in the water storage barrel 31.

Wherein, the throat pipe wall in the anaerobic layer 41 is spiral, the anaerobic layer 41 is formed by denitrifying biologic filler, when the airflow is flushed into the air storage cavity 42, the airflow is enabled to pass in a vortex shape by utilizing the throat pipe wall, and the effective mixing of the biologic filter material and the filler is ensured.

Wherein, the input ratio of the biological filter material in the charging barrel 28 to the biological filler in the anaerobic layer 41 is 1:2 to 1.

The valve port of the valve port pipe 34 is an electromagnetic valve port, and the electromagnetic valve port is convenient for the control system to control the closing of each channel.

Wherein, the sealing washer 16 has been cup jointed to the downcomer 15 and the storage bucket 31 junction, and 16 circle bodies of sealing washer are connected with storage bucket 31 bucket wall interference, and the upper end of sealing washer 16 runs through and is provided with the flowmeter, when guaranteeing that the water is stable to pass through 16 circle bodies of sealing washer, utilizes the flowmeter record to drain into the total amount of water in the storage bucket 31.

Wherein, the left side of the equipment box body 1 is fixed with an air pump 39, the air pump 39 comprises an air charging pipeline, one end of the air charging pipeline is communicated with the air pump 39, the other end of the air charging pipeline penetrates through the equipment box body 1 and then is inserted into the lower end of the back of the reaction barrel 38, the air pump 39 is communicated with the reaction chamber 40 through the air charging pipeline, when the air pump operates, air enters the reaction chamber 40 along with the air charging pipeline, and the air can be combined with residual water to wash the wall of the reaction chamber 40.

Wherein, the mesh specification of the filter screen 19 is selected according to the type specification of the selected biological filter material and biological filler.

As shown in fig. 1-7, the control system includes a flow box 5, a control box 9 and a cabinet 24; the flow box 5 is arranged at the upper end of the operating platform 6, the flow box 5 is embedded with the equipment box body 1, the flow box 5 is composed of a plurality of groups of water flow meters, and the input end of the flow box 5 is electrically connected with the output end of the storage battery 21; the cabinet 24 is embedded in the inner cavity 23, the cabinet 24 is embedded in the front end of the distribution box 22, the cabinet 24 is formed by splicing metal frame plates, a host 25 and a server 27 are arranged in the cabinet 24, the host 25 is fixed at the upper end of the server 27, the host 25 and the server 27 are both clamped with the inner wall of the cabinet 24, the host 25 is a processing system based on an artificial intelligent operating system, the operating system in the host 25 comprises a flow metering module and a valve port channel control module controlled by a PLC system, the flow metering module comprises a flow valve 32 and a flow meter which are contained in a water purification system, the output end of the flow metering module is electrically connected with the input end of the flow box 5, the valve port channel control module comprises electromagnetic valves distributed at each valve port and pipe orifice in the water purification system, the server 27 comprises a time servo control module, the time servo control module in the server 27 is electrically connected with the fan 29 and the air pump 39, and the output end of the server 27 is electrically connected with the input end of the host 25; the control box 9 is arranged at the left end of the right side wall of the equipment box body 1, the control box 9 is embedded with the equipment box body 1, a power supply button and an indicator light are distributed on the surface of the control box 9, the inner side of the control box 9 penetrates through the middle of the front face of the cabinet 24, a connection port plate 26 is fixed on the inner side of the control box 9, the connection port plate 26 is composed of a plurality of data interfaces and cable interfaces, and the connection port plate 26 is electrically connected with the host computer 25 through cables; the main machine 25 in the cabinet 24 mainly obtains real-time measurement data of the flow valve 32 and the flow meter through the flow measurement module, thereby obtaining the flow state of the water body, and controls the valve port channel control module according to the charging ratio of the biological filter material or the gas and the sewage flow by calculating the charging content of the fluid, the passing state of the electromagnetic valve port and the pipeline in the water purification system is opened and closed by the valve port channel control module, thereby controlling the water purification process of the water purification system, and the current distribution circuit of the power supply cabinet 8 is cut off or closed according to the time efficiency of the water purification process by the time servo control module in the server 27, thereby completing the intermittent drive control of the fan 29 and the air pump 39.

As shown in figures 1-7, the artificial intelligence-based cultivation sewage treatment method comprises the following steps:

and (3) an installation stage: the device box body 1 is placed in a water source area of a culture place in a transportation mode and the like, a culture sewage discharge pipeline is connected with a water inlet pipe 3, the water source pipeline is connected with a water outlet pipe 30, a water pump is arranged at the joint, and after a power supply cabinet 8 is connected with a power supply, an operator turns on the device through a switch of a control box 9;

and (3) a treatment stage: the discharged sewage is discharged into the sewage tank 2 through the water inlet pipe 3, and pipeline channels such as a valve port and the like are controlled through the control system host 25, so that the sewage sequentially passes through the equipment pipeline along the sequence from the upper tank 37, the return pipe 11, the lower tank 36, the sewage hose 35, the valve port pipe 34, the reaction barrel 38, the adapter pipe 33 to the water storage barrel 31;

a water purification stage; separating impurities such as fish corpses and the like in the sewage sequentially through an upper box 37 and a lower box 37, then sequentially carrying out nitration reaction in a reaction cavity 40 of a reaction barrel 38 to remove ammonia nitrogen in the sewage to produce nitric acid and carrying out denitrification reaction to degrade the nitric acid in the water, synchronously aerating the water body in the process, and finally filtering the impurities such as residual filter materials, fillers and the like in the water along with a filter pipe 7;

a circulation stage: the water after filtering is stored by water storage barrel 31, and the staff utilizes the water pump to pump the water in water storage barrel 31 for subsequent water culture so as to meet the requirement of culture water.

The apparatus in which the invention is applied:

the model of the storage battery is SG-50;

the model of the fan is R8-81D;

the model of the flow valve is FL-58;

the model of the flowmeter is LT-LDE;

the model of the air pump is YX-71D;

the model of the electromagnetic valve is ZCF51;

the above description is intended to describe in detail the preferred embodiments of the present invention, but the embodiments are not intended to limit the scope of the claims of the present invention, and all equivalent changes and modifications made within the technical spirit of the present invention should fall within the scope of the claims of the present invention.

Claims (9)

1. The utility model provides a breed sewage treatment device based on artificial intelligence which characterized in that: the method comprises the following steps:

the processing system comprises an equipment box body, a water inlet pipe, a power supply cabinet, a trough plate and a distribution box; the equipment box body is formed by splicing metal plates into a rectangular box body, an inner cavity is formed in a groove in the equipment box body, four corners of the bottom end of the equipment box body are respectively welded with a foot stand, the right side of the equipment box body is welded with an operation table, and the operation table is formed by splicing groove steel pieces; the groove plate is arranged at the upper end of the inner cavity and is clamped with the inner wall of the equipment box body, and the groove plate separates the space at the upper end of the inner cavity and forms a sewage tank; the water inlet pipe is arranged at the upper left end of the equipment box body, the water inlet pipe is fixedly connected with the side wall of the equipment box body, and a pipe orifice at one end of the water inlet pipe faces the sewage tank; the power cabinet is arranged at the lower end of the front side of the equipment box body, the power cabinet is embedded with the equipment box body, and a storage battery is embedded in the power cabinet; the distribution box is embedded in the inner cavity, the distribution box is fixed on the front surface of the inner cavity and is tightly attached to the power cabinet, the distribution box comprises a return pipe, a check valve, a lower box and an upper box, the upper box and the lower box are symmetrically embedded in the upper end and the lower end of the distribution box, the lower end of the lower box is provided with an L-shaped pipeline in a penetrating manner, the joint of the lower box and the L-shaped pipeline is sleeved with an electromagnetic valve, the upper end of the upper box is provided with a T-shaped pipe head, the T-shaped pipe head penetrates through a groove plate, the sewage groove is communicated with the upper box through the T-shaped pipe head, the return pipe and the check valve are provided with two pairs in total, the return pipe is a U-shaped pipeline, the check valve is arranged in the middle of the return pipe, the return pipe is symmetrically arranged at the left end and the right end of the front surface of the equipment box, the upper end and the lower end of the return pipe penetrate between the equipment box and the distribution box, the upper end and the lower end of the return pipe are respectively inserted in the upper box and the lower box, and the upper box are communicated with the lower box through the return pipe;

the water purification system comprises a filter pipe, a water storage barrel and a reaction barrel; the reaction barrel is embedded in the middle of an inner cavity, an air storage cavity and a reaction cavity which are mutually independent are formed at the upper end and the lower end of the inner side of the reaction barrel, a narrow-mouth channel is formed between the air storage cavity and the reaction cavity, an anaerobic layer is filled in the narrow-mouth channel, a pair of valve port pipes are inserted at the lower end of the reaction barrel, the valve port pipes are communicated with the reaction cavity, a sewage hose is arranged on the left side of each valve port pipe in a penetrating manner, the other end of each sewage hose is communicated with an L-shaped pipe in the lower box, each sewage hose is communicated with the reaction cavity through each valve port pipe, an adapter pipe is arranged at the lower end of each valve port pipe in a penetrating manner, a pipeline is inserted at the right side of each valve port pipe in a penetrating manner, the pipeline extends towards the right side and penetrates through an equipment box body, a fan is fixed at the lower end of the right side of the equipment box body, and a wind gap of the fan is communicated with the tail end of the pipeline; four filter tubes are arranged, the filter tubes are transversely arranged at equal intervals outside the upper end of the sewage tank, one end of each filter tube penetrates through the tank plate and then is communicated with the valve port pipe, the other end of the filter material pipe is provided with a charging barrel in a penetrating way, the charging barrel is fixedly connected with the equipment box body, and a biological filter material is added into the charging barrel; after being discharged from an L-shaped pipe of a lower box, sewage flows into a left valve port pipe along a sewage hose, a valve port between the valve port pipe and a switching pipe is closed, the sewage flows into a reaction cavity in a reaction barrel along a valve port pipe, a fan at the other end operates to evacuate airflow of a right pipeline of the valve port pipe, when the air pressure in the pipeline is smaller than the air pressure in a charging barrel, a biological filter material is discharged into the right valve port pipe along the airflow and then flows into the reaction cavity, when the sewage is full of the reaction cavity, the airflow carries the biological filter material and then flows into the reaction cavity along the lower end of the valve port pipe, the gas breaks through the airflow and then flows into an air storage cavity along a narrow-mouth channel and an anaerobic layer, in the process, the sewage and the biological filter material carry out nitration reaction in the reaction cavity, fish excrement and ammonia in the sewage react with the biological filter material to generate nitric acid and nitrous acid, synchronously, the airflow rushed in the process rushed into bubbles to promote the flow in the sewage while accelerating the contact of the biological filter material and the substances in the sewage when the biological filter material and the gas in the reaction cavity reach the threshold value of the air storage cavity, the oxygen content of the biological filter material, the biological filter material and the anaerobic layer to carry out denitrification reaction with the nitrification reaction cavity, the nitrification reaction of the sewage, and the sewage after the biological filter material are not influenced by the oxygen content of the free settling of the free air, and the free settling of the biological filter material;

the two water storage barrels are embedded into the right side of the inner cavity, the water storage barrels are positioned at the lower end of a pipeline on the right side of the valve port pipe, the water storage barrels are mutually communicated through a hose, a water outlet pipe is arranged at the right end of each water storage barrel in a penetrating mode, and the water outlet pipe penetrates through the back face of the equipment box body; the filter pipe is arranged in the middle of the right side of the equipment box body, the filter pipe is embedded with the equipment box body, the left end and the right end of the filter pipe are respectively provided with a connecting pipe and a water drain pipe in a penetrating way, one end of the connecting pipe penetrates through the equipment box body and is communicated with the adapter pipe, one end of the water drain pipe penetrates through the equipment box body and is communicated with the left end of the water storage barrel, a liquid cavity is formed in the filter pipe, a plug pipe head and a filter screen are embedded in the liquid cavity, the plug pipe head is embedded in the connecting pipe, a spiral pipe is arranged between the plug pipe head and the liquid cavity in a penetrating way, the pipe wall of the spiral pipe is in a spiral hole vortex shape, the filter screen is provided with ten pieces in total, the filter screen is transversely distributed in the liquid cavity at equal intervals, and the filter screen is clamped with the liquid cavity;

the control system comprises a flow box, a control box and a cabinet; the flow box is arranged at the upper end of the operating platform and is embedded with the equipment box body, the flow box is composed of a plurality of groups of water flow meters, and the input end of the flow box is electrically connected with the output end of the storage battery; the cabinet is embedded in the inner cavity and is embedded at the front end of the distribution box, the cabinet is formed by splicing metal frame plates, a host and a server are arranged in the cabinet, the host is fixed at the upper end of the server, the host and the server are both clamped with the inner wall of the cabinet, the host is a processing system based on an artificial intelligent operating system, the operating system in the host comprises a flow metering module and a valve port channel control module controlled by a PLC (programmable logic controller) system, the flow metering module comprises a flow valve and a flow meter contained in a water purification system, the output end of the flow metering module is electrically connected with the input end of the flow box, the valve port channel control module comprises electromagnetic valves distributed at each valve port and each orifice in the water purification system, the server comprises a time servo control module, the time servo control module in the server is electrically connected with a fan and an air pump, and the output end of the server is electrically connected with the input end of the host; the control box sets up in equipment box right side wall left end, the control box is rabbeted with the equipment box, control box surface distribution has power button and pilot lamp, the control box inboard runs through in the positive middle part of rack, the control box inboard is fixed with the connection port board, the connection port board comprises a plurality of data interface and cable interface, the connection port board passes through cable and host computer electric connection.

2. The artificial intelligence based aquaculture sewage treatment device of claim 1, wherein: the surface of the T-shaped pipe head at the upper end of the upper box is in a rectangular slotted hole shape, and flowmeters are arranged on the outer sides of the upper box and the lower box in a penetrating mode.

3. The artificial intelligence based aquaculture sewage treatment device of claim 1, wherein: the throat pipe wall in the anaerobic layer is spiral, and the anaerobic layer is formed by denitrifying biological fillers.

4. The artificial intelligence based aquaculture sewage treatment device of claim 1, wherein: the feeding ratio of the biological filter material to the anaerobic layer biological filler in the charging barrel is 1:2 to 1.

5. The artificial intelligence based aquaculture sewage treatment device of claim 1, wherein: and the pipe orifice at the joint of the valve port in the valve port pipe and the pipeline is the valve port of the electromagnetic valve.

6. The artificial intelligence based aquaculture sewage treatment device of claim 1, wherein: the water drain pipe is connected with the water storage barrel in a sleeved mode through a sealing ring, the ring body of the sealing ring is in interference connection with the barrel wall of the water storage barrel, and the upper end of the sealing ring is provided with a flow meter in a penetrating mode.

7. The artificial intelligence based aquaculture sewage treatment device of claim 1, wherein: an air pump is fixed on the left side of the equipment box body and comprises an air charging pipeline, one end of the air charging pipeline is communicated with the air pump, the other end of the air charging pipeline penetrates through the equipment box body and then is inserted into the lower end of the back face of the reaction barrel, and the air pump is communicated with the reaction cavity through the air charging pipeline.

8. The artificial intelligence based aquaculture sewage treatment device of claim 1, wherein: the specification of the meshes of the filter screen is selected according to the type specification of the selected biological filter material and biological filler.

9. The artificial intelligence based treatment method for the aquaculture wastewater treatment equipment based on any one of the claims 1 to 8, characterized by comprising the following steps:

and (3) an installation stage: the device box body is arranged in a water source area of a culture place in a transportation mode, a culture sewage discharge pipeline is connected with a water inlet pipe, a water source pipeline is connected with a water outlet pipe, a water pump is arranged at the joint, and an operator turns on the device through a switch of a control box after a power supply cabinet is connected with a power supply;

and (3) a treatment stage: the discharged sewage is discharged into a sewage tank through a water inlet pipe, and a valve port pipeline channel is controlled through a control system host machine, so that the sewage sequentially passes through equipment pipelines along the sequence from an upper tank, a return pipe, a lower tank, a sewage hose, a valve port pipe, a reaction barrel and a switching pipe to a water storage barrel;

a water purification stage; separating fish corpse impurities in the sewage by the upper tank and the lower tank, then carrying out nitration reaction in a reaction chamber of a reaction barrel to remove ammonia nitrogen in the sewage to produce nitric acid and carry out denitrification reaction to degrade the nitric acid in the water, carrying out synchronous aeration on a water body in the process, and finally filtering residual filter materials and filler impurities in the water along with a filtering pipe;

a circulation stage: the water after filtering is stored by the water storage barrel, and the staff utilizes the water pump to suck the water in the water storage barrel for subsequent water culture so as to meet the requirement of aquaculture water.

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