CN114163083B

CN114163083B - Floating type ocean sewage treatment device

Info

Publication number: CN114163083B
Application number: CN202111512581.3A
Authority: CN
Inventors: 汪顺义; 赵固
Original assignee: Heideway Technology Group Qingdao Co ltd
Current assignee: Heideway Technology Group Qingdao Co ltd
Priority date: 2021-12-11
Filing date: 2021-12-11
Publication date: 2022-11-11
Anticipated expiration: 2041-12-11
Also published as: CN114163083A

Abstract

The invention discloses a floating type ocean sewage treatment device, relates to the technical field of sewage treatment, and solves the problem that the existing device cannot intercept, separate and collect large-diameter floating garbage and sewage in sewage. The invention comprises a sundries storage bin which is fixedly connected with the top end of a primary filtering bin; the top end of the impurity storage bin is fixedly connected with an inclined reciprocating screw, the bottom of a ball nut seat of the inclined reciprocating screw is fixedly connected with a material returning grid, and the sewage treatment structure further comprises a connecting pipe B which is fixedly connected to the bottom of the rear end of the impurity storage bin; the ball nut seat can drive the material returning grid at the top of the ball nut seat to be pulled towards the rear side through the operation of the inclined reciprocating screw rod, the rod part of the material returning grid can penetrate through a gap in the intercepting grid to be pulled backwards, floating garbage can be pulled backwards to the inside of the impurity storage bin along the inclined intercepting grid, and the floating garbage with large diameter in sewage can be intercepted, separated and collected with the sewage.

Description

Floating type ocean sewage treatment device

Technical Field

The invention relates to the technical field of sewage treatment, in particular to a floating type ocean sewage treatment device.

Background

Domestic sewage and industrial waste produced in modern society are discharged into the sea to cause marine pollution, and a floating type marine sewage treatment device is needed.

Through retrieval, for example, patent No. CN211032939U discloses a floating type marine sewage treatment device, which comprises a hull and a water sump, and is characterized in that the water sump is installed on the hull, a sewage treatment structure is arranged on the hull and is positioned at one side of the water sump, a centrifugal water pumping structure is installed on the hull, a water inlet end of the centrifugal water pumping structure extends out of the hull, and a water outlet end of the centrifugal water pumping structure is communicated with the water sump; the centrifugal pumping structure comprises: the device comprises a first centrifugal pump, a telescopic connecting pipe, a support adjusting part and an anti-blocking isolating part; the garbage collection boat is used for solving the problems that in the prior art, garbage collection boats are mostly adopted to uniformly collect garbage concentrated areas floating on the sea, and pollutants such as polluted seawater, particularly floating oil floating on the sea, cannot be effectively treated.

For example, patent No. CN210341855U discloses a floating water pollution treatment device, which includes a salvage ship body, wherein a mounting plate is fixed on each of the left and right sides of the salvage ship body, the mounting plates are flush with the bottom of the salvage ship body, a floating plate perpendicular to the salvage ship body is built on each of the two mounting plates, a motor is fixed on each of the two ends of each of the two floating plates, a crawler belt is installed between the two motors, a plurality of claws for grabbing floaters are uniformly hinged on the crawler belt, and the motor drives the crawler belt to rotate so as to drive the claws to collect the grabbed garbage into the salvage ship body; the side, close to the track, of the side of the salvage ship body is designed to be a slope, a baffle is arranged on the slope, and when the claw hand moves to the slope along with the track, the baffle and the claw hand scrape each other to leave garbage. The scheme can be used for salvaging floaters, thereby reducing water pollution.

Based on the above, the conventional marine sewage treatment device is generally of a ship-shaped structure, and is not provided with a structure for controlling the entering amount of sewage with light surface layer mass through the relative height between the control device and the liquid level, so that large-diameter floating garbage and sewage in the sewage cannot be intercepted, separated and collected, and the structure for treating cyanide, organic matters, electroplating wastewater and phenol-containing wastewater in the sewage is not provided.

Therefore, the existing requirements are not met, and a floating type marine sewage treatment device is provided for the requirements.

Disclosure of Invention

Problem (A)

The invention aims to provide a floating type marine sewage treatment device, which solves the problems that the conventional marine sewage treatment device in the background art is generally of a ship-shaped structure, a structure capable of controlling the entering amount of sewage at different depths on a surface layer through the relative height of a control device and a liquid level is not arranged, large-diameter floating garbage and sewage in the sewage cannot be intercepted, separated and collected, and a structure capable of treating cyanide, organic matters, electroplating wastewater and phenol-containing wastewater in the sewage is not arranged.

(II) technical scheme

In order to achieve the purpose, the invention provides the following technical scheme: a floating type ocean sewage treatment device comprises a working cabin;

the bottom of the working cabin is of an arc structure, a first arc cabin is arranged at the front end of the working cabin, and an arc hole penetrates through the front end of the first arc cabin in the horizontal direction;

the working cabin is characterized in that a deck is fixedly connected to the top of the working cabin, a front frame is fixedly connected to the top of the front end of the deck, a vertical electric push rod is fixedly connected to the front end of the front frame, an arc-shaped protection plate is fixedly connected to the bottom end of a telescopic portion of the vertical electric push rod, a control system is fixedly connected to the top of the deck and comprises a control portion, the control portion is fixedly connected to the top of the deck, a satellite positioning and navigation system is arranged in the control portion, a satellite antenna is arranged at the rear end of the control portion and fixedly connected to the top of the deck, signals of the satellite antenna are coupled with the control portion, a solar cell panel is arranged on the rear side of the satellite antenna, and the solar cell panel is electrically connected with the control portion;

the left side and the right side of the working cabin are provided with floating height control structures, each floating height control structure comprises two groups of side plates, and the side plates are fixedly connected to vertical surfaces of the left side and the right side of the working cabin;

and a sewage treatment structure is arranged in the working cabin.

Preferably, the floating-height control structure further comprises:

the extension frame is fixedly connected to the side vertical face of the side plate;

the number of the soft air bags is two, and the soft air bags are fixedly connected to the tail end of the outer side of the extension frame.

Preferably, the floating-height control structure further comprises:

the flexible pipes are fixedly connected to the tops of the flexible air bags, the number of the flexible pipes is two, and the inner sides of the flexible pipes extend into the working cabin;

the electromagnetic valve A is arranged in the flexible pipe through flange connection;

the three-way pipe A is arranged at the joint of the two groups of flexible pipes through flange connection;

and the air control pump is arranged at the bottom of the three-way pipe A through flange connection.

Preferably, the sewage treatment structure includes:

the primary filtering bin is fixedly connected to the inside of the working cabin;

the water inlet pipe is fixedly connected to the front end of the primary filtering bin, and the front end of the water inlet pipe is fixedly connected to the inner side of the arc-shaped hole.

Preferably, the sewage treatment structure further comprises: the vertical reciprocating screw rods are arranged into two groups, the vertical reciprocating screw rods are fixedly connected to the vertical surfaces of the left side and the right side of the primary filtering bin, and the vertical reciprocating screw rod ball nut seat side vertical surface is fixedly connected with a stepping motor.

Preferably, the sewage treatment structure further comprises:

the middle shaft is arranged at the tail end of the inner side of the rotating shaft of the stepping motor through coaxial connection;

the convex block is fixedly connected to the side face of the middle shaft curve;

and the interception grid is fixedly connected to the vertical surface of the front end of the protruding block.

Preferably, the sewage treatment structure further comprises:

the bearing hook is fixedly connected to the bottom end of the interception gate;

and the connecting pipe A is fixedly connected to the rear end of the primary filter bin.

Preferably, the sewage treatment structure further comprises: the impurity storage bin is fixedly connected to the top end of the primary filtering bin; the top end of the impurity storage bin is fixedly connected with an inclined reciprocating screw, and the bottom of a ball nut seat of the inclined reciprocating screw is fixedly connected with a material returning grid.

Preferably, the sewage treatment structure further comprises a connecting pipe B, and the connecting pipe B is fixedly connected to the bottom of the rear end of the impurity storage bin; the inside of the connecting pipe B is fixedly connected with a filtrate net.

Preferably, the sewage treatment structure further comprises a pressure pump, the pressure pump is fixedly connected inside the working cabin and located at the rear end of the primary filtration cabin, a water inlet of the pressure pump is connected with the connecting pipe A and the connecting pipe B through a pipeline, a biomembrane sleeve is arranged at the rear end of the pressure pump through flange connection, a three-way pipe B is arranged at the rear end of the biomembrane sleeve through flange connection, an electromagnetic valve B is arranged on the right side of the three-way pipe B through flange connection, an ozone generator is arranged at the rear end of the electromagnetic valve B through flange connection, an electrolytic tank is arranged at the rear end of the three-way pipe B through flange connection, the top of the electrolytic tank is connected with the ozone generator through a pipeline, an electromagnetic valve C is arranged at the rear end of the electrolytic tank through flange connection, a drain pipe is arranged at the rear end of the electromagnetic valve C through flange connection, and the drain pipe extends to the outer side of the rear end of the working cabin.

(III) advantageous effects

1. According to the invention, through the arrangement of the floating height control structure, when sewage treatment is required, the electromagnetic valve A is controlled to be opened through the control part, so that air in the flexible air bags can be released through the flexible pipe at the top of the flexible air bags, the working cabin sinks, the bottom of the arc-shaped hole at the front end of the first arc-shaped cabin can be in contact with the horizontal plane, seawater can enter the water inlet pipe in the arc-shaped hole, and therefore, sewage enters the sewage treatment structure.

2. The invention also arranges a impurity storage bin, when sewage enters the front end of the primary filter bin through the water inlet pipe, floating garbage in the sewage can be intercepted through the intercepting grid at the front end of the primary filter bin, after the intercepting grid intercepts the floating garbage in the sewage, the control part controls two groups of vertical reciprocating screw rods to synchronously operate, so that the ball nut seat can drive the middle shaft at the inner side to vertically move upwards, when the middle shaft moves upwards to the top end, the control part controls two groups of stepping motors to synchronously operate, so that the rotating shaft drives the middle shaft to rotate, the middle shaft can drive the intercepting grid fixed at the front end of the middle shaft to rotate to be parallel to the inclined plane at the bottom of the impurity storage bin, and the inclined reciprocating screw rods are controlled to operate by the control part, so that the ball nut seat can drive the material returning grid at the top of the middle shaft to pull backwards, the material returning grid rod part passes through the gap at the inner side of the intercepting grid to pull backwards, so that the floating garbage can be pulled backwards along the inclined intercepting grid to the inner part of the impurity storage bin, and the floating garbage with large diameter in the sewage can be intercepted, separated and collected.

3. The invention also arranges the electrolytic tank, the filtered water flows into the ozone generator through the three-way pipe B, the control part controls the ozone generator to generate low-voltage current for electrolysis to generate ozone, the ozone is input into the electrolytic tank through the pipeline, and the oxidation-reduction reaction is enhanced through the input of the ozone while the electrolytic tank carries out electrolytic reduction on the sewage, thereby treating cyanide, organic matters, electroplating wastewater and phenol-containing wastewater in the sewage.

Drawings

FIG. 1 is a schematic perspective view of an embodiment of the present invention;

FIG. 2 is a schematic overall disassembled three-dimensional structure of the embodiment of the present invention;

FIG. 3 is an enlarged partial view of A in FIG. 2 according to the present invention;

FIG. 4 is a schematic perspective view of an embodiment of a trash bin of the present disclosure;

FIG. 5 is an enlarged partial view of section B in FIG. 4 according to the present invention;

FIG. 6 is a schematic side sectional perspective view of an initial filter bin according to an embodiment of the present invention;

FIG. 7 is a schematic perspective view of the front side of the bow-shaped cabin in an embodiment of the invention;

FIG. 8 is an enlarged partial view of section C of FIG. 7 according to the present invention;

FIG. 9 is a schematic perspective view of the rear side of the forward cambered cabin in the embodiment of the present invention;

in fig. 1 to 9, the correspondence between the part names or lines and the reference numbers is:

1. a working cabin;

101. a first arc-shaped cabin; 1011. an arc-shaped hole; 102. a deck; 1021. a front frame; 1022. a vertical electric push rod; 1023. an arc-shaped guard plate;

2. a side plate;

201. an extension frame; 202. a soft air bag; 2021. a flexible tube; 2022. an electromagnetic valve A; 2023. a three-way pipe A; 2024. a floating control air pump;

3. a control unit;

301. a satellite antenna; 302. a solar panel;

4. a primary filtering bin;

401. a water inlet pipe; 402. a vertically reciprocating lead screw; 403. a stepping motor; 404. a middle shaft; 4041. a protruding block; 405. an interception gate; 4051. a receiving hook; 406. a connecting pipe A;

5. a sundry storage bin;

501. inclining the reciprocating screw rod; 502. a material returning grid; 503. a connecting pipe B; 5031. a filtrate net;

6. a pressure pump;

601. a biofilm collar; 602. a three-way pipe B; 6021. a solenoid valve B;

7. an ozone generator;

8. an electrolytic cell;

801. a solenoid valve C; 802. and a water discharge pipe.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments.

In the description of the present invention, "a plurality" means two or more unless otherwise specified; the terms "upper", "lower", "left", "right", "inner", "outer", "front", "rear", "head", "tail", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are merely for convenience in describing the present invention and to simplify the description, and do not indicate or imply that the device or element referred to must have a particular orientation, be constructed in a particular orientation, and be operated, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," "third," and the like are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it should be noted that, unless explicitly stated or limited otherwise, the terms "connected" and "connected" are to be interpreted broadly, e.g., as being fixed or detachable or integrally connected; can be mechanically or electrically connected; may be directly connected or indirectly connected through an intermediate. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Referring to fig. 1 to 9, an embodiment of the present invention includes: a floating type marine sewage treatment device comprises a working cabin 1; the bottom of the working cabin 1 is of an arc structure, the rear end of the inner side of the working cabin 1 is provided with a power structure, the inside of the working cabin 1 is fixedly connected with a storage battery, the front end of the working cabin 1 is provided with a first arc cabin 101, and the front end of the first arc cabin 101 penetrates through an arc hole 1011 in the horizontal direction; the top of the working cabin 1 is fixedly connected with a deck 102, the top of the front end of the deck 102 is fixedly connected with a front frame 1021, the front end of the front frame 1021 is fixedly connected with a vertical electric push rod 1022, the bottom end of a telescopic part of the vertical electric push rod 1022 is fixedly connected with an arc-shaped guard plate 1023, the top of the deck 102 is fixedly connected with a control system, the control system comprises a control part 3, the control part 3 is fixedly connected with the top end of the deck 102, a satellite positioning and navigation system is arranged inside the control part 3, a satellite antenna 301 is arranged at the rear end of the control part 3, the satellite antenna 301 is fixedly connected with the top end of the deck 102, signals of the satellite antenna 301 are coupled with the control part 3, a solar cell panel 302 is arranged on the rear side of the satellite antenna 301, the solar cell panel 302 is electrically connected with the control part 3, electric power compensation can be carried out on the inside of the working cabin 1 through the solar cell panel 302, and the working duration of the device can be improved; floating height control structures are arranged on the left side and the right side of the working cabin 1, each floating height control structure comprises two groups of side plates 2, and the side plates 2 are fixedly connected to vertical surfaces on the left side and the right side of the working cabin 1; the inside sewage treatment structure that is provided with of work cabin 1, fix a position the navigation to work cabin 1 through satellite positioning navigation, can control work cabin 1 and carry out predetermined orbit tour.

As shown in fig. 1, 7 and 8, the floating-height control structure further includes: the extension frame 201, the extension frame 201 is fixedly connected to the side elevation of the side plate 2; the number of the soft air bags 202 is two, and the soft air bags 202 are fixedly connected to the outer end of the extension frame 201; the flexible pipes 2021 are fixedly connected to the top of the flexible air bag 202, the number of the flexible pipes 2021 is two, and the inner sides of the flexible pipes extend to the inside of the working cabin 1; the electromagnetic valve A2022 is arranged inside the flexible pipe 2021 through flange connection, and the electromagnetic valve A2022 is electrically connected with the control part 3; the three-way pipe A2023 is connected with the connecting part of the two groups of flexible pipes 2021 through a flange; the floating control air pump 2024 is arranged at the bottom of the three-way pipe A2023 through flange connection, when sewage treatment is needed, the electromagnetic valve A2022 is controlled to open through the control part 3, air inside the soft air bag 202 can be released through the flexible pipe 2021 at the top of the soft air bag, the working cabin 1 can sink, the bottom of the arc hole 1011 at the front end of the first arc cabin 101 can be contacted with the horizontal plane, seawater can enter the water inlet pipe 401 inside the arc hole 1011, so that sewage enters the sewage treatment structure, when the working cabin 1 needs to float, after the two groups of electromagnetic valves A2022 are controlled to open through the control part 3, the floating control air pump 2024 is controlled to operate simultaneously, gas conveying is carried out on the two groups of flexible pipes 2021 through the three-way pipe A2023, the soft air bags 202 on two sides of the working cabin 1 can be inflated, and the working cabin 1 can float integrally.

As shown in fig. 3 and 4, the sewage treatment structure includes: the primary filtering bin 4 is fixedly connected inside the working cabin 1; the water inlet pipe 401 is fixedly connected to the front end of the primary filtering bin 4, and the front end of the water inlet pipe is fixedly connected to the inner side of the arc-shaped hole 1011; the vertical reciprocating screw rods 402 are arranged in two groups, the vertical reciprocating screw rods 402 are fixedly connected to the vertical surfaces of the left side and the right side of the primary filter bin 4, and the electrical property of the vertical reciprocating screw rods is connected with the control part 3; a stepping motor 403, the stepping motor 403 is fixedly connected to the vertical face of the ball nut seat of the vertical reciprocating screw 402, and the electrical property of the stepping motor 403 is connected with the control part 3; a middle shaft 404, which is coaxially connected to the inner end of the rotating shaft of the stepping motor 403; a protruding block 4041 fixedly connected to the curved side of the middle shaft 404; the intercepting fence 405 and the intercepting fence 405 are fixedly connected to the front end vertical face of the protruding block 4041, and when sewage enters the front end of the primary filtering bin 4 through the water inlet pipe 401, floating garbage in the sewage can be intercepted through the intercepting fence 405 at the front end of the primary filtering bin 4.

As shown in fig. 5 and 6, the sewage treatment structure further includes: a receiving hook 4051, wherein the receiving hook 4051 is fixedly connected to the bottom end of the intercepting gate 405; the connecting pipe A406, the connecting pipe A406 is fixedly connected to the rear end of the primary filter bin 4; the impurity storage bin 5 is fixedly connected to the top end of the primary filtering bin 4; an inclined reciprocating screw 501 fixedly connected to the top end of the impurity storage bin 5; the material returning grid 502 is fixedly connected to the bottom of the ball nut seat of the inclined reciprocating screw 501; the connecting pipe B503 is fixedly connected to the bottom of the rear end of the impurity storage bin 5; the filtrate net 5031 is fixedly connected inside the connecting pipe B503, after the interception grid 405 intercepts floating garbage in sewage, the control unit 3 controls the two sets of vertical reciprocating screws 402 to synchronously operate, so that the ball nut seat of the interception grid drives the middle shaft 404 at the inner side to vertically move upwards, when the middle shaft 404 moves upwards to the top end, the control unit 3 controls the two sets of stepping motors 403 to synchronously operate, so that the rotating shaft of the control unit can drive the middle shaft 404 to rotate, so that the middle shaft 404 drives the interception grid 405 fixed at the front end of the interception grid to rotate to be parallel to the inclined surface at the bottom of the impurity storage bin 5, and the control unit 3 controls the inclined reciprocating screw 501 to operate, so that the ball nut seat of the control unit can drive the material returning grid 502 at the top of the interception grid to pull towards the rear side, so that the rod part of the material returning grid 502 can pull backwards through a gap inside the interception grid 405, so that the floating garbage can be pulled backwards to the impurity storage bin 5 along the inclined interception grid 405, and the floating garbage with large diameter in sewage can be separated and collected.

As shown in fig. 7 and 8, the sewage treatment structure further comprises a pressure pump 6, the pressure pump 6 is fixedly connected inside the working chamber 1 and is located at the rear end of the primary filtering bin 4, a water inlet of the pressure pump 6 is connected with a connecting pipe a406 and a connecting pipe B503 through a pipeline, a biofilm casing 601 is arranged at the rear end of the pressure pump 6 through a flange connection, a plurality of layers of biofilms are transversely arranged inside the biofilm casing 601, a three-way pipe B602 is arranged at the rear end of the biofilm casing 601 through a flange connection, an electromagnetic valve B6021 is arranged at the right side of the three-way pipe B602 through a flange connection, the electromagnetic valve B6021 is electrically connected with the control part 3, an ozone generator 7 is arranged at the rear end of the electromagnetic valve B6021 through a flange connection, an electrolytic tank 8 is arranged at the rear end of the three-way pipe B602 through a flange connection, the electric property of the electrolytic tank 8 is connected with the control part 3, the top of the electrolytic tank 8 is connected with the ozone generator 7 through a pipeline, the ozone generator 7 is electrically connected with the control part 3, the rear end of the electrolytic tank 8 is provided with an electromagnetic valve C801 through flange connection, the electromagnetic valve C801 is electrically connected with the control part 3, the rear end of the electromagnetic valve C801 is provided with a drain pipe 802 through flange connection, the drain pipe 802 extends to the outer side of the rear end of the working cabin 1, the residual sewage in the impurity storage cabin 5 flows into the pressure pump 6 through a connecting pipe B503 at the bottom of the rear end of the electromagnetic valve C801, the floating garbage can be separated through a filtrate net 5031 in the connecting pipe B503, the sewage after primary filtration can enter the pressure pump 6 through matching with the connecting pipe A406, the operation of the pressure pump 6 is controlled by the control part 3, the sewage can be pressurized to enter the rear biomembrane sleeve 601, the organic pollutants in the sewage can be filtered through multilayer biomembrane filtration, the filtered water flows into the ozone generator 7 through a three-way pipe B602, the control part 3 controls the interior of the ozone generator 7 to emit low-pressure current to electrolyze and generate ozone, ozone can be input into the electrolytic cell 8 through a pipeline, and cyanide, organic matters, electroplating wastewater and phenol-containing wastewater in the sewage can be treated by inputting ozone to enhance oxidation-reduction reaction while the electrolytic cell 8 carries out electrolytic reduction on the sewage.

In another embodiment of the present invention, a remote control system is provided in the control part 3, so that a user can remotely control the direction of the movement of the work cabin 1 by radio, and receiving a user signal through the satellite antenna 301.

The working principle is as follows:

when the device is used, after the whole device is put into seawater, a user remotely controls the control part 3 through remote radio, and can also position and navigate the working cabin 1 through a satellite positioning and navigation system, so that the working cabin 1 can be controlled to patrol a preset track in a polluted area, when sewage treatment is needed, the electromagnetic valve A2022 is controlled to be opened through the control part 3, air in the soft air bag 202 can be released through the flexible pipe 2021 at the top of the soft air bag, the working cabin 1 can sink, the bottom of the arc-shaped hole 1011 at the front end of the first arc-shaped cabin 101 can be contacted with a horizontal plane 1011, seawater can enter the inside of the water inlet pipe 401 in the arc-shaped hole, so that sewage enters a sewage treatment structure, when the working cabin 1 needs to float, the floating air pump 2024 is controlled to operate simultaneously after the two groups of electromagnetic valves A2022 are controlled to be opened through the control part 3, two groups of flexible pipes 2021 are conveyed by gas through a three-way pipe A2023, so that the soft air bags 202 at two sides of the working cabin 1 are inflated, the whole working cabin 1 can float upwards, after the working cabin 1 sinks, when sewage enters the front end of the primary filtering cabin 4 through the water inlet pipe 401, floating garbage in the sewage can be intercepted through the intercepting grid 405 at the front end of the primary filtering cabin 4, after the floating garbage in the sewage is intercepted by the intercepting grid 405, the two groups of vertical reciprocating screw rods 402 are controlled by the control part 3 to synchronously operate, so that the ball nut seats thereof can drive the central shaft 404 at the inner side to vertically move upwards, when the central shaft 404 moves upwards to the top end, the control part 3 controls the two groups of stepping motors 403 to synchronously operate, so that the rotating shaft thereof can drive the central shaft 404 to rotate, the central shaft 404 can drive the intercepting grid 405 fixed at the front end thereof to rotate to be parallel to the inclined plane at the bottom of the impurity storage cabin 5, and the inclined reciprocating screw rods 501 are controlled by the control part 3 to operate, the ball nut seat can drive the material returning grid 502 at the top of the ball nut seat to be pulled towards the rear side, the rod part of the material returning grid 502 can be pulled backwards through a gap inside the intercepting grid 405, floating garbage can be pulled backwards along the inclined intercepting grid 405 to the inside of the impurity storage bin 5, large-diameter floating garbage in sewage can be separated from the sewage and collected, the residual sewage in the impurity storage bin 5 flows into the pressurizing pump 6 through a connecting pipe B503 at the bottom of the connecting pipe B503, the floating garbage can be separated through a filtrate net 5031 in the connecting pipe B503, the sewage after primary filtration can enter the pressurizing pump 6 through matching with the connecting pipe A406, the pressurizing pump 6 is controlled to operate through the control part 3, the sewage can be pressurized to enter the inside of a rear biomembrane sleeve 601, organic pollutants in the sewage can be filtered through multilayer biomembrane filtration, the filtered water flows into the ozone generator 7 through the control part 3, low-voltage current can be generated through electrolysis to generate electricity, ozone can be input into the electrolytic tank 8 through a pipeline, ozone can be used for carrying out ozone reduction reaction on the sewage in the electrolytic tank 8, and wastewater containing organic matter can be subjected to reduction reaction, and wastewater containing organic matter can be input into the electrolytic tank for electroplating, and wastewater can be treated through a three-way of the ozone generator.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims

1. The utility model provides a float formula ocean sewage treatment plant which characterized in that: comprises a working cabin (1);

the bottom of the working cabin (1) is of an arc-shaped structure, a first arc-shaped cabin (101) is arranged at the front end of the working cabin (1), and an arc-shaped hole (1011) penetrates through the front end of the first arc-shaped cabin (101) in the horizontal direction; the working cabin comprises a working cabin body (1), a deck (102) is fixedly connected to the top of the working cabin body (1), a front frame (1021) is fixedly connected to the top of the front end of the deck (102), a vertical electric push rod (1022) is fixedly connected to the front end of the front frame (1021), an arc-shaped guard plate (1023) is fixedly connected to the bottom end of a telescopic portion of the vertical electric push rod (1022), a control system is fixedly connected to the top of the deck (102) and comprises a control portion (3), the control portion (3) is fixedly connected to the top end of the deck (102), a satellite positioning and navigation system is arranged inside the control portion (3), a satellite antenna (301) is arranged at the rear end of the control portion (3), the satellite antenna (301) is fixedly connected to the top end of the deck (102), signals of the satellite antenna (301) are coupled to the control portion (3), a solar cell panel (302) is arranged on the rear side of the satellite antenna (301), and the solar cell panel (302) is electrically connected to the control portion (3); floating height control structures are arranged on the left side and the right side of the working cabin (1), each floating height control structure comprises two groups of side plates (2), and the side plates (2) are fixedly connected to vertical surfaces on the left side and the right side of the working cabin (1);

the inside sewage treatment structure that is provided with of work cabin (1), sewage treatment structure includes: the primary filtering bin (4), the primary filtering bin (4) is fixedly connected to the inside of the working cabin (1); inlet tube (401), its fixed connection is in prefiltration storehouse (4) front end, and its front end fixed connection is inboard in arc hole (1011), and the sewage treatment structure still includes: perpendicular reciprocal lead screw (402), its quantity sets up to two groups, perpendicular reciprocal lead screw (402) fixed connection in the just filtration storehouse (4) left and right sides facade department, perpendicular reciprocal lead screw (402) ball nut seat side facade fixedly connected with step motor (403), sewage treatment structure still includes: the middle shaft (404) is arranged at the tail end of the inner side of the rotating shaft of the stepping motor (403) through coaxial connection; the convex block (4041) is fixedly connected to the curved side surface of the middle shaft (404); the interception grid (405) is fixedly connected to the front end vertical face of the protruding block (4041); the sewage treatment structure further comprises: the impurity storage bin (5), the impurity storage bin (5) is fixedly connected to the top end of the primary filtering bin (4); the top end of the impurity storage bin (5) is fixedly connected with an inclined reciprocating screw rod (501), and the bottom of a ball nut seat of the inclined reciprocating screw rod (501) is fixedly connected with a material returning grid (502);

the sewage treatment structure also comprises a connecting pipe B (503), and the connecting pipe B (503) is fixedly connected to the bottom of the rear end of the impurity storage bin (5); the inner part of the connecting pipe B (503) is fixedly connected with a filtrate net (5031); the sewage treatment structure further comprises a pressure pump (6), the pressure pump (6) is fixedly connected to the inside of the working cabin (1) and is positioned at the rear end of the primary filtering bin (4), a water inlet of the pressure pump is connected with a connecting pipe A (406) and a connecting pipe B (503) through a pipeline, and a biomembrane sleeve (601) is arranged at the rear end of the pressure pump (6) through a flange connection; the rear end of the biofilm casing pipe (601) is provided with a three-way pipe B (602) through flange connection, the right side of the three-way pipe B (602) is provided with an electromagnetic valve B (6021) through flange connection, and the rear end of the electromagnetic valve B (6021) is provided with an ozone generator (7) through flange connection; the rear end of the three-way pipe B (602) is provided with an electrolytic tank (8) through flange connection, the top of the electrolytic tank (8) is connected with an ozone generator (7) through a pipeline, the rear end of the electrolytic tank (8) is provided with an electromagnetic valve C (801) through flange connection, the rear end of the electromagnetic valve C (801) is provided with a drain pipe (802) through flange connection, and the drain pipe (802) extends to the outer side of the rear end of the working cabin (1).

2. A floating marine wastewater treatment plant according to claim 1, characterized in that said floating height control structure further comprises: the extension frame (201), the extension frame (201) is fixedly connected to the side vertical face of the side plate (2); the number of the soft air bags (202) is two, and the soft air bags (202) are fixedly connected to the tail end of the outer side of the extension frame (201).

3. A floating marine wastewater treatment plant according to claim 2, characterized in that the floating height control structure further comprises: the flexible pipes (2021), the flexible pipes (2021) are fixedly connected to the top of the soft air bag (202), the number of the flexible pipes is two, and the inner side of the flexible pipes extends to the inside of the working cabin (1); the electromagnetic valve A (2022), the electromagnetic valve A (2022) is arranged inside the flexible pipe (2021) through flange connection; the three-way pipe A (2023) is connected with the joint of the two groups of flexible pipes (2021) through a flange; the air control pump (2024) is arranged at the bottom of the three-way pipe A (2023) through flange connection.

4. The floating marine wastewater treatment plant according to claim 1, wherein the wastewater treatment structure further comprises: the bearing hook (4051), the bearing hook (4051) is fixedly connected to the bottom end of the intercepting grid (405); and the connecting pipe A (406) is fixedly connected to the rear end of the primary filtering bin (4).