CN116199352B - A push type aeration equipment for sewage treatment - Google Patents

Abstract

The invention discloses a push type aeration device for sewage treatment, which comprises a buoyancy adjustable floating device, a pushing device, a follow-up type aeration device, an automatic sampling device and an environment-friendly power supply device, wherein the pushing device is arranged at the side end and the bottom of the buoyancy adjustable floating device, the follow-up type aeration device penetrates through the buoyancy adjustable floating device and is arranged in water below the buoyancy adjustable floating device, the follow-up type aeration device realizes lifting aeration effect along with buoyancy adjustment of the buoyancy adjustable floating device, and the automatic sampling device is arranged on one side of the buoyancy adjustable floating device. The invention belongs to the technical field of sewage treatment, and particularly provides a push type aeration device for sewage treatment, which realizes the movable effect of aeration, realizes the variation of aeration in a small range in the vertical direction under the adjustable action of buoyancy, improves the flexibility and the aeration effect, and then extracts and collects a water sample in advance, thereby facilitating the subsequent relative static sampling and having less influence on the sampling result and accuracy.

Description

A push type aeration equipment for sewage treatment

Technical Field

The invention belongs to the technical field of sewage treatment related equipment, and particularly relates to a push type aeration device for sewage treatment.

Background

Common technical means in the sewage treatment process comprise primary treatment, secondary treatment and tertiary treatment. Wherein, first-stage treatment: after being lifted by a sewage lifting pump, the raw sewage passing through the coarse grating passes through the grating or a sand filter and then enters a sand setting tank, and the sewage after sand-water separation enters a primary sedimentation tank; and (3) secondary treatment: the effluent of the primary sedimentation tank enters biological treatment equipment, wherein the biological treatment equipment comprises an activated sludge method and a biological membrane method (an aeration tank, an oxidation ditch and the like are arranged in a reactor of the activated sludge method), the effluent of the biological treatment equipment enters a secondary sedimentation tank, and the effluent of the secondary sedimentation tank is disinfected and discharged or enters a third-stage treatment; and (3) three-stage treatment: including biological denitrification and dephosphorization, coagulation precipitation, sand filtration, activated carbon adsorption, ion exchange and electrodialysis. After passing through the dewatering and drying equipment, the sludge is finally utilized.

The activated sludge method in the secondary treatment process needs a reactor aeration tank, aeration equipment is needed in the aeration tank, the aeration equipment is an equipment for forcibly adding air into sewage, so that the sewage in the tank is in contact with the air to oxygenate, the liquid is stirred, the transfer of oxygen in the air into the liquid is accelerated, the suspension in the tank is prevented from sinking, the contact of organic matters in the tank, microorganisms and dissolved oxygen is enhanced, and the oxidative decomposition equipment is carried out on the organic matters in the sewage.

For the above prior art, the following disadvantages are included:

1. aeration treatment is carried out by adopting blast aeration equipment, the aeration position is relatively fixed, the flexibility is insufficient, the fixed-point aeration treatment is carried out in a pool with larger volume, and the aeration effect is poor; a plurality of aeration devices in a water area are required to work simultaneously, so that cost and resource waste are caused;

2. in the existing equipment, the structure of aeration sampling is less, the sampling is not carried out in the aeration process, and the sewage treatment progress cannot be mastered in time; in addition, since the agitation of the water surface of the aeration tank is severe, a general sampler cannot realize stable sampling data.

Disclosure of Invention

Aiming at the situation, in order to overcome the defects of the prior art, the invention provides the propelling type aeration equipment for sewage treatment, which has the advantages that under the action of the buoyancy adjustable floating device, the variation of aeration in a small range in the vertical direction is realized, under the action of the propelling device, the movable effect of aeration is realized, the flexibility and the aeration effect are improved, and under the action of the automatic sampling device, the water sample is extracted and collected in advance, so that the follow-up relative static sampling is facilitated, and the sampling result and the accuracy are less influenced.

The technical scheme adopted by the invention is as follows: the invention relates to a push type aeration device for sewage treatment, which comprises a buoyancy adjustable floating device, a pushing device, a follow-up type aeration device, an automatic sampling device and an environment-friendly power supply device, wherein the pushing device is arranged at the side end of the buoyancy adjustable floating device and the bottom of the buoyancy adjustable floating device, the two outer sides of the top of the buoyancy adjustable floating device are respectively and outwards extended to be provided with a horizontally arranged sampling supporting table and an aeration supporting table, the automatic sampling device is arranged on the sampling supporting table, the bottoms of the automatic sampling device and the sampling supporting table are communicated with a water body below, the follow-up type aeration device is arranged on the aeration supporting table, the other end of the follow-up type aeration device penetrates through the buoyancy adjustable floating device and is arranged in the water body below, the environment-friendly power supply device is arranged between the sampling supporting table and the aeration supporting table, and the environment-friendly power supply device is the buoyancy adjustable floating device, the pushing device, the follow-up type aeration device and the automatic sampling device.

As a further elaboration scheme, the buoyancy-adjustable floating device comprises a floating plate, floating pipes, transverse connecting pieces and buoyancy-adjustable air bag components, wherein the floating pipes are uniformly distributed along a plane, the transverse connecting pieces are connected and arranged between the adjacent floating pipes, the floating plate is arranged at the outer sides of the two outer side floating pipes, the buoyancy-adjustable air bag components can be deformed and arranged in the floating pipes, and the connection parts of the buoyancy-adjustable air bag components and the floating pipes are connected in a sealing manner; the buoyancy adjustable airbag assembly comprises an inflation motor, an active turntable, an eccentric rotating shaft, a driving fixing plate, a connecting rod, an inflation pump, a piston rod, an inflation telescopic pipe, an inflation airbag and a limiting piece, wherein a motor support is arranged at the inner bottom of the flotation pipe, the inflation motor is arranged on the motor support, the active turntable is rotatably arranged on the side wall of the flotation pipe, an output shaft of the inflation motor is connected with the center of the active turntable, the eccentric rotating shaft is eccentric and vertically arranged on the active turntable, the driving fixing plate is vertically connected in the flotation pipe, the inflation pump is horizontally arranged on the driving fixing plate, the piston rod is arranged at the inflation end of the inflation pump in a reciprocating mode along the horizontal direction, the connecting rod is connected with the free end of the eccentric rotating shaft, the piston rod is connected in the inflation pump in a telescopic mode, openings at two sides of the flotation pipe are arranged at the opening of the flotation pipe, the inflation airbag is slidably arranged in the telescopic slideway, the limiting piece is arranged at the tail end of the inside the flotation pipe, the diameter of the limiting piece is larger than that the telescopic slideway, the diameter of the telescopic slideway is equal to the driving fixing plate, the driving plate is not separated from the inflation pump, and the inflation pump is connected with the inflation pump.

In the scheme, the bottom of the floating pipe is provided with the balance weight cavity, the balance weight cavity is made of a hollow material, water inlets are formed in two sides of the bottom, the water inlets are obliquely arranged at the lower opening, and the balance weight cavity is arranged so that the balance weight cavity is always positioned at the bottom when the floating pipe is positioned in water or on the water surface, and the balance weight effect is achieved; the top of float pipe has seted up the intake pipe, the height of intake pipe is higher than the height of horizontal plane far away, plays the effect of intaking in the float pipe.

In the scheme, the automatic sampling device comprises a lifting type water sample acquisition component and a movable type water sample acquisition component, wherein the lifting type water sample acquisition component is arranged on a sampling support table, and the movable type water sample acquisition component is arranged on the lifting type water sample acquisition component; the lifting type water sample acquisition component comprises a lifting motor, a driving worm, a driven worm wheel ring, a driving gear, a linkage rotating shaft, a rotating shaft support, a lower hinge support rod, an upper hinge support rod and a sampling disc, wherein the driven worm wheel ring is rotationally arranged above the sampling support table, an upper sampling hole is formed in the center of the driven worm wheel ring, a lower sampling hole is formed in the center of the sampling support table, the upper sampling hole and the lower sampling hole are correspondingly arranged, worm gear teeth are arranged on the periphery of the driven worm wheel ring, a motor support is arranged on one side of the lower sampling hole of the sampling support table, the lifting motor is arranged on the motor support, a worm support is further arranged on one side of the motor support, the driving worm is rotationally arranged between the worm supports, an output shaft of the lifting motor is connected with the driving worm, and the driving worm is meshed with a worm gear of the driven worm wheel teeth of the driven worm wheel ring, the driven worm wheel ring is uniformly provided with a rotating shaft support at the periphery of the upper sampling hole, the linkage rotating shaft is rotationally arranged on the rotating shaft support, the driving gear is connected and arranged on one side of the linkage rotating shaft, a spur gear is arranged at the top circumference of the driven worm wheel ring, peripheral gear teeth of the driving gear are meshed with top gear teeth of the spur gear, the lower hinge support rod is hinged with the other end of the linkage rotating shaft, the upper hinge support rod is hinged with the free end of the lower hinge support rod, the upper hinge support rod and the lower hinge support rod form a V-shaped structure with a variable angle, in the preferred scheme, four groups of driving gears, the linkage rotating shaft, the rotating shaft support, the lower hinge support rod and the upper hinge support rod are correspondingly arranged at the periphery of the sampling disc, the sampling plate has a certain depth for accommodating water, and is provided with a support rack for accommodating unmanned aerial vehicle, and the portable sampling effect is convenient.

As the technical scheme who further states, portable water sample collection subassembly includes sampling storehouse, upper cover, removal paddle, rotating electrical machines, rotor pole, gas-liquid separation subassembly, sampling pump, connecting rod, landing leg and sampling tube, the sampling storehouse is open-top's cavity setting, on the open-top in sampling storehouse was located to the upper cover, the four corners department of upper cover is located to the rotor pole, rotating electrical machines locates rotor pole one end, just on the output shaft of rotating electrical machines is located to the removal paddle, the bottom in sampling storehouse is located to landing leg symmetry connection, plays the supporting role on the landing leg locates the supporting rack, the bottom in sampling storehouse is located to gas-liquid separation subassembly intercommunication, the sampling pump is located in the sampling storehouse, the sampling tube intercommunication is located gas-liquid separation subassembly's bottom one side, the sampling tube is equipped with the multiunit and is linked together, the sampling tube is linked together with the water in the sampling dish, adjacent be equipped with the connecting rod support between the sampling tube, gas-liquid separation subassembly adopts the cyclone separator in the prior art to realize the gas-liquid separation effect, gas upwards discharges into in the sampling storehouse, liquid is located the bottom in gas-liquid separation subassembly, preferably is equipped with the swirl hole in the bottom in the preferred scheme, the bottom is equipped with the liquid outlet.

In further scheme, be equipped with division board, sampling pipe, treater and radio communication ware in the sampling storehouse, the division board is located inside the sampling storehouse, sampling pump, treater and radio communication ware are located on the division board, in the sampling storehouse was located to the sampling pipe, the sampling pump is linked together with the sampling pipe, still is equipped with current equipment such as locator, battery in this scheme in the sampling storehouse, does not do too much in this scheme and repeating, can realize remote operation's effect.

Further, the propulsion device comprises a side end propulsion component and a bottom propulsion component, wherein the side end propulsion component is arranged at the side end of the floating plate, the bottom propulsion component is arranged at the bottom of the floating pipe, the bottom propulsion component comprises a motor fixing piece, a brushless motor, a protective shell and a propeller, the motor fixing piece is connected to the bottom of the floating pipe, the brushless motor is fixedly arranged at the bottom of the motor fixing piece, the protective shell is arranged at the bottom of the other side of the motor fixing piece, the propeller is rotationally arranged in the protective shell, and an output shaft of the brushless motor is arranged at the center of the propeller; the side end propulsion assembly comprises screw side paddles symmetrically arranged on two sides of the floating plate, the screw side paddles positioned outside the same side floating plate are driven by a driving belt, and a driving piece is electrically connected to the center of the screw side paddles.

As a preferable scheme, the driving belt is a waterproof driving belt, and the protective shell is a PU pipe.

Further, follow-up aeration equipment includes hollow post, air supply pipeline, gas distribution divide pipe, aeration component and air-blower, the bottom of floating board is located perpendicularly to the hollow post, just the hollow post is connected with buoyancy adjustable floating device through lower ring flange, the air-blower is located on the aeration brace table, the one end of air supply pipeline is linked together with the air-out end of air-blower, the other end of air supply pipeline is equipped with gas pressurization room through last ring flange and lower ring flange joint, the bottom of hollow post is equipped with gas pressurization room, gas distribution divides the pipe to set up along gas pressurization room's periphery department evenly distributed, aeration component installs the tail end of locating gas distribution branch pipe.

As a further elaboration, the aeration element takes the form of a bubble generator adapted to convert the gas introduced into the bubble generator into a plurality of bubbles, thereby achieving the effect of aeration.

In the preferred scheme, the hollow column is symmetrically arranged about the floating plates at two sides, the air supply pipeline is arranged in a Y shape, and the follow-up aeration devices are symmetrically arranged at two sides of the bottom of the floating plates.

As the preferred scheme, environmental protection power supply unit includes solar cell panel, bracing piece one, bracing piece two, support storage seat, photovoltaic charge controller and battery, on the both sides of locating the float board, just bracing piece one, bracing piece two are perpendicular to be connected respectively the length that is longer than bracing piece two, solar cell panel is the slope form and connects locates between bracing piece one and the top of bracing piece two, support storage seat locates between solar cell panel's interior bottom and one side of float board, the inside cavity of support storage seat sets up and the outside has seted up the louvre, battery and photovoltaic charge controller locate in the support storage seat, photovoltaic charge controller electricity is connected and is located between solar cell panel and the battery, the battery is whole equipment power supply.

The beneficial effects obtained by the invention by adopting the structure are as follows: according to the scheme, under the buoyancy adjustable action of the buoyancy adjustable floating device, the change of the aeration in a small range in the vertical direction is realized, under the action of the pushing device, the movable effect of the aeration is realized, the flexibility and the aeration effect are improved, under the action of the automatic sampling device, a water sample is extracted and collected in advance, the subsequent relative static sampling is facilitated, the sampling result and the accuracy are less influenced, and the environment-friendly performance of the overall structure is improved, and the power supply for the overall device is realized.

Drawings

Fig. 1 is a schematic diagram of the overall structure of a push aeration device for sewage treatment according to the present disclosure;

fig. 2 is a front view showing a part of the construction of the push type aeration apparatus for sewage treatment according to the present embodiment;

FIG. 3 is a schematic view of the buoyancy-adjustable bladder assembly and the flotation tube in this embodiment;

FIG. 4 is a schematic diagram of a lifting water sample acquisition assembly in this embodiment;

FIG. 5 is a schematic diagram of a three-dimensional structure of a lifting water sample acquisition assembly in this embodiment;

FIG. 6 is a schematic diagram of the structure of FIG. 5 absent a sampling plate;

FIG. 7 is a schematic top view of the drive part of the elevating water sample acquisition assembly in this embodiment;

FIG. 8 is a schematic structural view of a follow-up aeration device in the present embodiment;

FIG. 9 is a schematic diagram of a mobile water sample collection assembly in this embodiment;

fig. 10 is a schematic diagram of the internal structure of the mobile water sample collection assembly according to this embodiment.

Wherein 1, buoyancy adjustable floating device, 2, propulsion device, 3, follow-up aeration device, 4, automatic sampling device, 5, environment-friendly power supply device, 6, sampling support table, 7, aeration support table, 8, floating plate, 9, floating pipe, 10, transverse connection piece, 11, buoyancy adjustable air bag component, 12, aeration motor, 13, driving turntable, 14, eccentric rotating shaft, 15, driving fixed plate, 16, connecting rod, 17, aeration pump, 18, piston rod, 19, aeration telescopic pipe, 20, aeration air bag, 21, limiting piece, 22, sealing piece, 23, counterweight cavity, 24, water inlet, 25, air inlet pipe, 26, lifting water sample acquisition component, 27, mobile water sample acquisition component, 28, lifting motor, 29, driving worm, 30, driven worm wheel ring, 31, driving gear, 32, linkage rotating shaft, 33, rotating shaft support, the device comprises a lower hinged support rod, 35, an upper hinged support rod, 36, a sampling device, 37, a side end propelling component, 38, a bottom propelling component, 39, a motor fixing component, 40, a brushless motor, 41, a protective shell, 42, a propeller, 43, a transmission belt, 44, a hollow column, 45, a gas supply component, 46, a gas distribution component, 47, an aeration component, 48, a blower, 49, an upper flange plate, 50, a lower flange plate, 51, a gas pressurizing chamber, 52, a propeller, 54, a solar panel, 55, a first support rod, 56, a second support rod, 57, a support containing seat, 58, a photovoltaic charging controller, 59, a battery, 60, an upper sampling hole, 61, a spur gear, 62, a support rack, 63, a sampling bin, 64, an upper cover, 65, a movable blade, 66, a rotary motor, 67, a rotor rod, 68, a gas-liquid separation component, 69, a connecting rod, 70, a supporting leg, 71, a main body and a main body, sampling tube 72, division board 73, sampling tube 74, processor 75, wireless communicator 76, liquid outlet hole 77, sampling pump.

The accompanying drawings are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate the invention and together with the embodiments of the invention, serve to explain the invention.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are only some, but not all embodiments of the invention; all other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

As shown in fig. 1-2, the push-type aeration equipment for sewage treatment comprises a buoyancy-adjustable floating device 1, a push-in device 2, a follow-up aeration device 3, an automatic sampling device 4 and an environment-friendly power supply device 5, wherein the push-in device 2 is arranged at the side end of the buoyancy-adjustable floating device 1 and the bottom of the buoyancy-adjustable floating device 1, a sampling supporting table 6 and an aeration supporting table 7 which are horizontally arranged are respectively and outwards extended from the two outer sides of the top of the buoyancy-adjustable floating device 1, the automatic sampling device 4 is arranged on the sampling supporting table 6, the bottoms of the automatic sampling device 4 and the sampling supporting table 6 are communicated with water below, the follow-up aeration device 3 is arranged on the aeration supporting table 7, the other end of the follow-up aeration device 3 penetrates through the buoyancy-adjustable floating device 1 and is arranged in the water below, the follow-up aeration device 3 realizes a lifting aeration effect along with the buoyancy adjustment of the buoyancy-adjustable floating device 1, the environment-friendly power supply device 5 is arranged between the sampling supporting table 6 and the aeration supporting table 7, and the environment-friendly power supply device 5 is provided with the buoyancy-adjustable floating device 1, the bottom, the automatic sampling device 2 and the follow-up aeration device 4 are respectively.

Referring to fig. 2 and 3, the buoyancy-adjustable floating device 1 comprises floating plates 8, floating pipes 9, transverse connectors 10 and buoyancy-adjustable air bag assemblies 11, wherein the floating pipes 9 are uniformly distributed along a plane, the transverse connectors 10 are connected and arranged between adjacent floating pipes 9, the floating plates 8 are arranged at the outer sides of the two outer floating pipes 9, the buoyancy-adjustable air bag assemblies 11 are flexibly arranged in the floating pipes 9, and the connection parts of the buoyancy-adjustable air bag assemblies 11 and the floating pipes 9 are in sealing connection; the buoyancy adjustable airbag assembly 11 comprises an inflation motor 12, an active turntable 13, an eccentric rotating shaft 14, a driving fixing plate 15, a connecting rod 16, an inflation pump 17, a piston rod 18, an inflation telescopic pipe 19, an inflation airbag 20 and a limiting piece 21, wherein the motor bracket is arranged at the inner bottom of the floating pipe 9, the inflation motor 12 is arranged on the motor bracket, the active turntable 13 is rotatably arranged on the side wall of the floating pipe 9, an output shaft of the inflation motor 12 is connected with the center of the active turntable 13, the eccentric rotating shaft 14 is eccentrically and vertically arranged on the active turntable 13, the driving fixing plate 15 is vertically connected and arranged in the floating pipe 9, the inflation pump 17 is horizontally arranged on the driving fixing plate 15, the piston rod 18 is reciprocally arranged at the inflation end of the inflation pump 17 along the horizontal direction, the connecting rod 16 is connected with the free end of the eccentric rotating shaft 14, the connecting rod 16 is connected with the piston rod 18 in the inflation pump 17 in a telescopic manner, two side openings of the floating pipe 9 are arranged at the opening of the floating pipe 9, the inflation airbag 20 is slidably arranged in the telescopic slideway, the limiting piece 21 is arranged at the tail end of the inside the floating pipe 9, the diameter of the limiting piece 21 is larger than the telescopic slideway, the diameter of the telescopic air bag 20 is not separated from the driving telescopic air bag 20, the sealing effect is achieved, and the inflation telescopic air bag 20 is not separated from the driving the inflation telescopic air pump 19, and the inflation telescopic air pump is arranged between the driving air pump 19 and the inflation pump 17 and the driving fixing plate and the inflation telescopic pipe and the inflation pipe.

In the preferred scheme, the bottom of the floating pipe 9 is provided with a counterweight cavity 23, the counterweight cavity 23 is made of a hollow material, water inlets 24 are formed in two sides of the bottom, the water inlets 24 are obliquely arranged at the lower opening, and the counterweight cavity 23 is arranged so that the counterweight cavity 23 is always positioned at the bottom when the floating pipe 9 is positioned in water or on the water surface, thereby achieving the effect of counterweight; the top of the floating pipe 9 is provided with an air inlet pipe 25, and the height of the air inlet pipe 25 is far higher than the height of the horizontal plane, so that the air inlet function in the floating pipe 9 is achieved.

As shown in fig. 1 and 2, the propulsion device 2 comprises a side end propulsion assembly 37 and a bottom propulsion assembly 38, the side end propulsion assembly 37 is arranged at the side end of the floating plate 8, the bottom propulsion assembly 38 is arranged at the bottom of the floating pipe 9, the bottom propulsion assembly 38 comprises a motor fixing piece 39, a brushless motor 40, a protecting shell 41 and a propeller 42, the motor fixing piece 39 is connected to the bottom of the floating pipe 9, the brushless motor 40 is fixedly arranged at the bottom of the motor fixing piece 39, the protecting shell 41 is arranged at the bottom of the other side of the motor fixing piece 39, the propeller 42 is rotatably arranged in the protecting shell 41, and an output shaft of the brushless motor 40 is arranged at the center of the propeller 42; the side end propulsion component 37 comprises screw side paddles 52 symmetrically arranged on two sides of the floating plate 8, the screw side paddles 52 positioned outside the floating plate 8 on the same side are driven by a driving belt 43, a driving piece is electrically connected to the center of the screw side paddles 52, the driving belt 43 is a waterproof driving belt 43, and the protective shell 41 is a PU tube.

As shown in fig. 4, 5, 6, 7, 9 and 10, the automatic sampling device 4 comprises a lifting type water sample acquisition component 26 and a movable type water sample acquisition component 27, wherein the lifting type water sample acquisition component 26 is arranged on the sampling support table 6, and the movable type water sample acquisition component 27 is arranged on the lifting type water sample acquisition component 26; the lifting type water sample acquisition component 26 comprises a lifting motor 28, a driving worm 29, a driven worm wheel ring 30, a driving gear 31, a linkage rotating shaft 32, a rotating shaft support 33, a lower hinge support rod 34, an upper hinge support rod 35 and a sampling disc 36, wherein the driven worm wheel ring 30 is rotationally arranged above the sampling support table 6, an upper sampling hole 60 is formed in the center of the driven worm wheel ring 30, a lower sampling hole is formed in the center of the sampling support table 6, the upper sampling hole 60 is correspondingly arranged with the lower sampling hole, worm gear teeth are arranged on the periphery of the driven worm wheel ring 30, a motor support is arranged on one side of the lower sampling hole of the sampling support table 6, the lifting motor 28 is arranged on the motor support, a worm support is further arranged on one side of the motor support, the driving worm 29 is rotationally arranged between the worm support seats, an output shaft of the lifting motor 28 is connected with the driving worm 29, the driving worm 29 is meshed with the worm gear teeth of the driven worm wheel ring 30, the driven worm wheel ring 30 is uniformly provided with a rotating shaft support 33 at the periphery of the up-sampling hole 60, the linkage rotating shaft 32 is rotationally arranged on the rotating shaft support 33, the driving gear 31 is connected and arranged on one side of the linkage rotating shaft 32, the top circumference of the driven worm wheel ring 30 is provided with a spur gear 61, the peripheral gear teeth of the driving gear 31 are meshed with the top gear teeth of the spur gear 61, the lower hinge support rod 34 is hinged with the other end of the linkage rotating shaft 32, the upper hinge support rod 35 is hinged with the free end of the lower hinge support rod 34, the upper hinge support rod 35 and the lower hinge support rod 34 form a V-shaped structure with a variable angle, in the preferred scheme, the driving gear 31, the linkage rotating shaft 32, the rotating shaft support 33, the lower hinge support rod 34 and the upper hinge support rod 35 are correspondingly provided with four groups, the top free ends of the four groups of the upper hinge support rods 35 are hinged and arranged at the periphery of the sampling disc 36, the sampling plate 36 has a certain depth for containing water, and the sampling plate 36 is provided with a support rack 62 for supporting the unmanned aerial vehicle, thereby facilitating the movable sampling effect.

As shown in fig. 9 and 10, as a further explanation technical scheme, the mobile water sample collection assembly 27 includes a sampling bin 63, an upper cover 64, a moving blade 65, a rotating motor 66, a rotor rod 67, a gas-liquid separation assembly 68, a sampling pump 77, a connecting rod 69, a supporting leg 70 and a sampling tube 71, the sampling bin 63 is a hollow cavity with an open top, the upper cover 64 is arranged on the open top of the sampling bin 63, the rotor rod 67 is arranged at four corners of the upper cover 64, the rotating motor 66 is arranged at one end of the rotor rod 67, the moving blade 65 is arranged on an output shaft of the rotating motor 66, the supporting leg 70 is symmetrically connected to the bottom of the sampling bin 63, the supporting leg 70 is arranged on a supporting rack 62 to play a supporting role, the gas-liquid separation assembly 68 is communicated to the bottom of the sampling bin 63, the sampling pump 77 is arranged in the sampling bin 63, the sampling tube 71 is communicated to the bottom side of the gas-liquid separation assembly 68, the sampling tube 71 is communicated with the water in the sampling tray 36, the connecting rod 69 is arranged between the adjacent sampling tubes 71 to support, the gas-liquid separation assembly 68 adopts the cyclone separator in the prior art to realize the gas-liquid separation effect, the gas-liquid separation bin is discharged upwards, the gas-liquid separation assembly is preferably arranged at the bottom of the gas-liquid separation assembly 68, and the gas-liquid separation assembly is provided with a liquid outlet 76, and the bottom hole 76 is preferably arranged in the bottom hole is arranged at the bottom of the gas separation assembly.

In the preferred scheme, be equipped with division board 72, sampling pipe 73, treater 74 and radio communication ware 75 in the sampling storehouse 63, division board 72 locates sampling storehouse 63 inside, sampling pump 77, treater 74 and radio communication ware 75 locate on division board 72, sampling pipe 73 locates in the sampling storehouse 63, sampling pump 77 is linked together with sampling pipe 73, in this scheme, still be equipped with existing equipment such as locator, battery 59 in the sampling storehouse 63, do not do too much in this scheme and repeated the effect that can realize remote operation.

As shown in fig. 8, the follow-up aeration device 3 comprises a hollow column 44, an air supply pipeline 45, a gas distribution branch pipe 46, aeration elements 47 and an air blower 48, wherein the hollow column 44 is vertically arranged at the bottom of the floating plate 8, the hollow column 44 is connected with the buoyancy adjustable floating device 1 through a lower flange 50, the air blower 48 is arranged on the aeration supporting table 7, one end of the air supply pipeline 45 is communicated with the air outlet end of the air blower 48, the other end of the air supply pipeline 45 is in flange connection with the lower flange 50 through an upper flange 49, the bottom of the hollow column 44 is provided with a gas pressurizing chamber 51, the gas distribution branch pipe 46 is uniformly distributed along the periphery of the gas pressurizing chamber 51, the aeration elements 47 are arranged at the tail end of the gas distribution branch pipe 46, the aeration elements 47 adopt a bubble generator form and are suitable for converting the gas introduced into the bubble generator into a plurality of bubbles, so that the aeration effect is realized. And the hollow columns 44 are symmetrically arranged about the floating plates 8 at the two sides, the air supply pipeline 45 is arranged in a Y shape, and the follow-up aeration devices 3 are symmetrically arranged at the two sides of the bottom of the floating plates 8.

In the preferred scheme, the environment-friendly power supply device 5 comprises a solar cell 59 plate 54, a first supporting rod 55, a second supporting rod 56, a supporting containing seat 57, a photovoltaic charge controller 58 and a battery 59, wherein the first supporting rod 55 and the second supporting rod 56 are respectively and vertically connected to two sides of the floating plate 8, the length of the first supporting rod 55 is longer than that of the second supporting rod 56, the solar cell 59 plate 54 is obliquely connected between the first supporting rod 55 and the top of the second supporting rod 56, the supporting containing seat 57 is arranged between the inner bottom of the solar cell 59 plate 54 and one side of the floating plate 8, a heat dissipation hole is formed in the supporting containing seat 57 in a hollow mode, the battery 59 and the photovoltaic charge controller 58 are arranged in the supporting containing seat 57, the photovoltaic charge controller 58 is electrically connected between the solar cell 59 plate 54 and the battery 59, and the battery 59 supplies power for the whole device.

When the buoyancy-adjustable floating device 1 is specifically used, under the buoyancy-adjustable action of the buoyancy-adjustable floating device 1, when the air-charging motor 12 works, the output shaft of the air-charging motor 12 drives the driving turntable 13 to rotate, the driving turntable 13 rotates to drive the eccentric rotating shaft 14 to rotate, the eccentric rotating shaft 14 drives the connecting rod 16 to eccentrically move, the piston rod 18 is driven by the connecting rod 16 to reciprocate along the horizontal direction and is arranged at the air-charging end of the air-charging pump 17, the air-charging motor 12 is a stepping motor rotating in the forward and reverse directions, the air-charging effect on the air-charging air bags 20 is realized during the reciprocating movement, the air-charging air bags 20 are provided with a plurality of groups side by side, after the air-charging, the buoyancy of the whole equipment can be changed, so that the depth in a water body is adjusted, and the follow-up aeration device 3 is driven to realize the variation of the vertical small-range aeration; under the action of the propulsion device 2, the movable aeration effect is realized, and the flexibility and the aeration effect are improved; under the effect of automatic sampling device 4, draw the water sample in advance and gather, elevator motor 28 drives initiative worm 29 rotation, thereby initiative worm 29 meshing driven worm wheel ring 30's periphery worm wheel teeth, thereby make driven worm wheel ring 30 rotatory, driven worm wheel ring 30's top circumference department is equipped with straight-tooth gear 61, the periphery teeth of drive gear 31 mesh with the top teeth of straight-tooth gear 61, in the in-process of rotatory removal, go up articulated bracing piece 35 and lower articulated bracing piece 34 constitution angle variable V-arrangement, and V-arrangement's opening direction means sampling dish 36 is located driven worm wheel ring 30's top or below, heavy-calibre sampling dish 36 conveniently carries out the sample to the water, the relative static sampling of follow-up has been made things convenient for, be equipped with support rack 62 on the sampling dish 36, be used for accepting portable water sample collection assembly 27, after moving to sampling dish 36, sampling pump 77 work, sampling tube 71 is linked together with the water in the sampling dish 36, sample through sampling 71 to the water, produce less influence to sampling result and accuracy, and through the effect of gas-liquid separation assembly 68, make the separation with the water sample tube, the environmental protection device is realized and the environmental protection performance is improved, the environmental protection is realized and the whole environmental protection device is convenient for the aeration device is realized, the overall environmental protection and the performance is improved, the aeration device is convenient to have been set up.

It is noted that relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

The invention and its embodiments have been described above with no limitation, and the actual construction is not limited to the embodiments of the invention as shown in the drawings. In summary, if one of ordinary skill in the art is informed by this disclosure, a structural manner and an embodiment similar to the technical solution should not be creatively devised without departing from the gist of the present invention.

Claims (7)

1. A push aeration device for sewage treatment, characterized in that: the device comprises a buoyancy adjustable floating device (1), a propelling device (2), a follow-up type aeration device (3), an automatic sampling device (4) and an environment-friendly power supply device (5), wherein the propelling device (2) is arranged at the side end of the buoyancy adjustable floating device (1) and at the bottom of the buoyancy adjustable floating device (1), the two outer sides of the top of the buoyancy adjustable floating device (1) are respectively and outwards extended to be provided with a horizontally arranged sampling supporting table (6) and an aeration supporting table (7), the automatic sampling device (4) is arranged on the sampling supporting table (6), the bottoms of the automatic sampling device (4) and the sampling supporting table (6) are all communicated with a water body below, the follow-up type aeration device (3) is arranged on the aeration supporting table (7), the other end of the follow-up type aeration device (3) penetrates through the buoyancy adjustable floating device (1) and is arranged in the water below, the buoyancy adjustable floating device (3) is used for adjusting, the lifting aeration effect of the buoyancy adjustable floating device (1), the environment-friendly device (5) is arranged between the power supply supporting table (6) and the environment-friendly power supply device (7), the follow-up type aeration device (1) and the environment-friendly power supply device (3) The automatic sampling device (4) is powered;

the buoyancy adjustable floating device (1) comprises floating plates (8), floating pipes (9), transverse connecting pieces (10) and buoyancy adjustable air bag components (11), wherein the floating pipes (9) are uniformly distributed along a plane, the transverse connecting pieces (10) are connected and arranged between the adjacent floating pipes (9), the floating plates (8) are arranged at the outer sides of the two outer side floating pipes (9), the buoyancy adjustable air bag components (11) are deformable and arranged in the floating pipes (9), and the joints of the buoyancy adjustable air bag components (11) and the floating pipes (9) are connected in a sealing mode; the buoyancy adjustable air bag component (11) comprises an air charging motor (12), a driving turntable (13), an eccentric rotating shaft (14), a driving fixing plate (15), a connecting rod (16), an air charging pump (17), a piston rod (18), an air charging telescopic pipe (19), an air charging air bag (20) and a limiting piece (21), wherein a motor support is arranged at the inner bottom of the floating pipe (9), the air charging motor (12) is arranged on the motor support, the driving turntable (13) is rotatably arranged on the side wall of the floating pipe (9), an output shaft of the air charging motor (12) is connected with the center of the driving turntable (13), the eccentric rotating shaft (14) is eccentrically and vertically arranged on the driving turntable (13), the driving fixing plate (15) is vertically connected and arranged in the floating pipe (9), the air charging pump (17) is horizontally arranged on the driving fixing plate (15), the piston rod (18) is reciprocally arranged at the air charging end of the air charging pump (17) along the horizontal direction, the connecting rod (16) is connected with the free end of the rotating shaft (14), the connecting rod (16) is connected with the connecting rod (18) and is connected with the air charging pump (17) and is provided with the sliding slide way (20) which is arranged in the sliding slide way of the floating pipe (9, the limiting piece (21) is arranged at the tail end of the inflatable air bag (20) in the floating pipe (9), the diameter of the limiting piece (21) is larger than that of the telescopic slide way, the inflatable air bag (20) cannot be completely separated from the floating pipe (9), the inflatable air bag (19) is communicated between the air outlet end of the inflator pump (17) and the inflatable air bag (20), and a sealing piece (22) is arranged at the joint of the inflatable air bag (19) and the driving fixing plate (15);

the bottom of the floating pipe (9) is provided with a balance weight cavity (23), the balance weight cavity (23) is made of a hollow material, water inlets (24) are formed in two sides of the bottom, the water inlets (24) are obliquely arranged at the lower opening, and the balance weight cavity (23) is arranged so that the balance weight cavity (23) is always positioned at the bottom when the floating pipe (9) is positioned in water or on the water surface; an air inlet pipe (25) is arranged at the top of the floating pipe (9), the height of the air inlet pipe (25) is far higher than that of the horizontal plane, and the air inlet pipe (25) is used for introducing air into the floating pipe (9);

the automatic sampling device (4) comprises a lifting type water sample acquisition component (26) and a movable type water sample acquisition component (27), wherein the lifting type water sample acquisition component (26) is arranged on the sampling support table (6), and the movable type water sample acquisition component (27) is arranged on the lifting type water sample acquisition component (26); the lifting type water sample acquisition assembly (26) comprises a lifting motor (28), a driving worm (29), a driven worm wheel ring (30), a driving gear (31), a linkage rotating shaft (32), a rotating shaft support (33), a lower hinged support rod (34), an upper hinged support rod (35) and a sampling disc (36), wherein the driven worm wheel ring (30) is rotationally arranged above the sampling support table (6), an upper sampling hole (60) is formed in the center of the driven worm wheel ring (30), a lower sampling hole is formed in the center of the sampling support table (6), the upper sampling hole (60) is arranged corresponding to the lower sampling hole, worm wheel teeth are formed in the periphery of the driven worm wheel ring (30), a motor support is arranged on one side of the lower sampling hole of the sampling support table (6), the lifting motor (28) is arranged on the motor support, one side of the motor support is also provided with a worm support, the driving worm (29) is rotationally arranged between the worm supports, an output shaft of the lifting motor (28) is connected with the driving worm (29), the driving worm (29) is meshed with the worm wheel teeth of the driven worm wheel ring (30) on the rotating shaft (33), the rotating shaft (33) is uniformly arranged on the rotating shaft (32), the utility model provides a water sample collection device, including drive gear (31) and driven worm wheel ring (30), drive gear (31) are connected to locate on one side of linkage pivot (32), the top circumference department of driven worm wheel ring (30) is equipped with straight gear (61), the periphery teeth of a cogwheel (31) mesh with the top teeth of a cogwheel (61), articulated bracing piece (34) are articulated mutually with the other end of linkage pivot (32) down, go up articulated bracing piece (35) and articulated bracing piece (34)'s free end mutually articulated down, go up articulated bracing piece (35) and articulated bracing piece (34) constitution angle variable V-arrangement structure down, in the preferred scheme, drive gear (31), linkage pivot (32), pivot support (33), articulated bracing piece (34) down, go up articulated bracing piece (35) all correspond and are equipped with four sets of articulated the periphery department of locating sampling dish (36) in top free end of last articulated bracing piece (35), sampling dish (36) have a certain degree of depth to be used for splendid attire water, and be equipped with on sampling dish (36) and support rack (62) for accepting portable water sample collection subassembly (27).

2. A push aeration device for sewage treatment according to claim 1, wherein: the movable water sample collection assembly (27) comprises a sampling bin (63), an upper cover (64), a movable blade (65), a rotating motor (66), a rotary motor (67), a gas-liquid separation assembly (68), a sampling pump (77), a connecting rod (69), a supporting leg (70) and a sampling tube (71), wherein the sampling bin (63) is arranged in a hollow cavity with an opening at the top, the upper cover (64) is arranged on the opening at the top of the sampling bin (63), the rotary motor (66) is arranged at four corners of the upper cover (64), one end of the rotary motor (66) is arranged at one end of the rotary motor (67), the movable blade (65) is arranged on an output shaft of the rotating motor (66), the supporting leg (70) is symmetrically connected to the bottom of the sampling bin (63), the supporting leg (70) is arranged on a supporting rack (62) to play a supporting role, the gas-liquid separation assembly (68) is communicated with the bottom of the sampling bin (63), the sampling pump (77) is arranged in the sampling bin (63), the sampling tube (71) is arranged on one side of the bottom of the sampling tube (68) which is communicated with the gas-liquid separation assembly (68), a plurality of groups of the connecting rods (71) are arranged in the supporting plates (71), the gas-liquid separation assembly (68) adopts a cyclone separator to realize the gas-liquid separation effect, gas is upwards discharged into the sampling bin (63) through the cyclone head, liquid is downwards located at the bottom of the gas-liquid separation assembly (68), a liquid outlet hole (76) is formed in the bottom of the gas-liquid separation assembly (68), and a plug cover is arranged at the liquid outlet hole (76).

3. A push aeration device for sewage treatment according to claim 2, wherein: be equipped with division board (72), sampling pipe (73), treater (74) and wireless communicator (75) in sampling storehouse (63), inside sampling storehouse (63) are located to division board (72), sampling pump (77), treater (74) and wireless communicator (75) are located on division board (72), in sampling storehouse (63) are located to sampling pipe (73), sampling pump (77) are linked together with sampling pipe (73).

4. A push aeration device for sewage treatment according to claim 3, wherein: the propulsion device (2) comprises a side end propulsion component (37) and a bottom propulsion component (38), wherein the side end propulsion component (37) is arranged at the side end of the floating plate (8), the bottom propulsion component (38) is arranged at the bottom of the floating pipe (9), the bottom propulsion component (38) comprises a motor fixing piece (39), a brushless motor (40), a protective shell (41) and a propeller (42), the motor fixing piece (39) is connected to the bottom of the floating pipe (9), the brushless motor (40) is fixedly arranged at the bottom of the motor fixing piece (39), the protective shell (41) is arranged at the bottom of the other side of the motor fixing piece (39), the propeller (42) is rotatably arranged in the protective shell (41), and an output shaft of the brushless motor (40) is arranged at the center of the propeller (42); the side end propulsion assembly (37) comprises screw side paddles (52) symmetrically arranged on two sides of the floating plate (8), the screw side paddles (52) positioned on the outer portion of the same side of the floating plate (8) are driven by a driving belt (43), and driving parts are electrically connected at the center of the screw side paddles (52).

5. A push aeration device for wastewater treatment according to claim 4 and wherein: the follow-up aeration device (3) comprises a hollow column (44), an air supply pipeline (45), a gas distribution branch pipe (46), an aeration element (47) and a blower (48), wherein the hollow column (44) is vertically arranged at the bottom of a floating plate (8), the hollow column (44) is connected with a buoyancy adjustable floating device (1) through a lower flange plate (50), the blower (48) is arranged on an aeration supporting table (7), one end of the air supply pipeline (45) is communicated with the air outlet end of the blower (48), the other end of the air supply pipeline (45) is connected with the lower flange plate (50) through an upper flange plate (49), a gas pressurizing chamber (51) is arranged at the bottom of the hollow column (44), the gas distribution branch pipe (46) is uniformly distributed along the periphery of the gas pressurizing chamber (51), and the aeration element (47) is arranged at the tail end of the gas distribution branch pipe (46).

6. A push aeration device for wastewater treatment according to claim 5 and wherein: the environment-friendly power supply device (5) comprises a solar cell (59) plate (54), a first supporting rod (55), a second supporting rod (56), a supporting storage seat (57), a photovoltaic charging controller (58) and a battery (59), wherein the first supporting rod (55) and the second supporting rod (56) are respectively and vertically connected to the two sides of the floating plate (8), the length of the first supporting rod (55) is longer than that of the second supporting rod (56), the solar cell (59) plate (54) is obliquely connected between the first supporting rod (55) and the top of the second supporting rod (56), the supporting storage seat (57) is arranged between the inner bottom of the solar cell (59) plate (54) and one side of the floating plate (8), a radiating hole is formed in the supporting storage seat (57), the battery (59) and the photovoltaic charging controller (58) are arranged in the supporting storage seat (57), and the photovoltaic charging controller (58) is electrically connected between the solar cell (59) plate (54) and the battery (59), and the battery (59) is an integral power supply device.

7. A push aeration device for wastewater treatment according to claim 6 and wherein: the driving belt (43) is a waterproof driving belt (43), and the protecting shell (41) is a PU pipe; the aeration element (47) takes the form of a bubble generator, converting the gas introduced into the bubble generator into a plurality of bubbles; the hollow columns (44) are symmetrically arranged about the floating plates (8) at two sides, the air supply pipeline (45) is arranged in a Y shape, and the follow-up aeration devices (3) are symmetrically arranged at two sides of the bottom of the floating plates (8).