CN115353266B

CN115353266B - Sewage suction device and process for biologically treating wastes

Info

Publication number: CN115353266B
Application number: CN202211126477.5A
Authority: CN
Inventors: 王石平
Original assignee: Guangzhou Kaizhida Chemical Industries Ltd; Beijing Railway Materials Co ltd Materials Supply Branch
Current assignee: Guangzhou Kaizhida Chemical Industries Ltd; Beijing Railway Materials Co ltd Materials Supply Branch
Priority date: 2022-09-16
Filing date: 2022-09-16
Publication date: 2023-03-21
Anticipated expiration: 2042-09-16
Also published as: CN115353266A

Abstract

The invention relates to the field of sewage suction equipment, in particular to a sewage suction device for biologically treating wastes and a process thereof. The technical problem is as follows: in the process of cleaning up dirt in a motor car toilet, when a drainage pipeline is led out and is blocked, most of the blockage is dredged in a manual digging or tool assisting mode, in the process, liquid dung and the blockage in the pipeline flow downwards along the drainage pipeline and drop on a motor car track and motor car mechanical parts, and the liquid dung and the blockage are attached to the motor car track and the motor car mechanical parts for a long time, so that the motor car track and the motor car mechanical parts are corroded and damaged. The technical scheme is as follows: a sewage suction device for biological treatment of waste comprises a housing, a collection assembly and the like; a collection assembly is positioned at the front of the housing. The invention realizes the cleaning of the liquid dung in the toilet of the bullet train, dredges the blockage in the sewage discharge pipeline of the bullet train in a negative pressure mode and dredges the blockage in a sealing mode.

Description

Sewage suction device and process for biologically treating wastes

Technical Field

The invention relates to the field of sewage suction equipment, in particular to a sewage suction device for biologically treating wastes and a process thereof.

Background

At present, china high-speed motor cars adopt an autonomous manufacturing standard, a toilet system is arranged on the high-speed motor cars adopting the autonomous manufacturing standard to provide services for passengers, the requirements of the passengers can be well met, but the high-speed motor cars cannot be cleaned in time when the toilet system is used for a long time in the operation process, so that the phenomena of peculiar smell emission, pipeline scaling, even blockage and the like often occur in the use process of the toilet system, and the cleaning is difficult.

In the prior art, in the process of cleaning dirt in a washroom of a motor car, when a drainage pipeline is led out and is blocked, most of the blockage is dredged in a manual dredging or tool assisting mode, liquid dung and the blockage in the pipeline flow downwards along the drainage pipeline and drop on a motor car track and a motor car mechanical part, and the liquid dung and the blockage are attached to the motor car track and the motor car mechanical part for a long time, so that the motor car track and the motor car mechanical part are corroded and damaged; the existing excrement water separation mode adopts a mode of accumulating in large quantity and separating again, and in the process, due to the long-time accumulation in large quantity, the ammonia nitrogen concentration in the excrement is overhigh, and the explosion risk is overhigh.

Disclosure of Invention

In order to overcome the defect that in the process of cleaning dirt in a washroom of a motor car, when a drainage pipeline is led to be blocked, most of the blockage is dredged in a manual digging or tool assisting mode, in the process, liquid dung and the blockage in the pipeline flow downwards along the drainage pipeline and drop on a motor car track and a motor car mechanical part, and the liquid dung and the blockage are attached to the motor car track and the motor car mechanical part for a long time, so that the motor car track and the motor car mechanical part are corroded and damaged; the existing excrement-water separation mode adopts a mode of mass accumulation and re-separation, and in the process, due to the mass accumulation for a long time, the ammonia nitrogen concentration in the excrement is too high, so that the explosion risk is too high.

The technical scheme of the invention is as follows: a sewage suction device for biologically treating wastes comprises a shell, a collecting component, a separating frame, a first connecting plate, a cleaning component, a connecting cylinder, a plugging ring, an elastic plug, a winding component, a filtering cylinder, a second connecting rod and a fifth connecting plate; a collecting component is arranged at the front part of the shell; the collecting component is connected with two bilaterally symmetrical separating frames for separating the blocking objects; the shell is connected with a cleaning component; the collecting component is connected with the cleaning component; the interior of the cleaning component is connected with a connecting cylinder; an elastic plug is connected inside the connecting cylinder in a sliding manner; a plugging ring for sealing the sewage discharge pipe is connected inside the cleaning component; the winding component is connected inside the shell; the cleaning component is connected with the winding component; the interior of the shell is connected with a filtering component; the winding component is connected with the filtering component; the filtering component is connected with a filtering cylinder for separating liquid dung; the filter assembly is connected with a plurality of second connecting rods for shifting the filter cartridges; the filter component is connected with a plurality of fifth connecting plates used for scraping the blockage on the filter cartridge.

More preferably, the inner wall of the connecting cylinder is provided with four annular-array sliding grooves.

More preferably, the plugging ring is of a rubber structure and has elasticity.

More preferably, the second connecting rod is provided with an inverted conical extrusion block.

More preferably, the collecting assembly comprises a moving frame, a collecting box, a drawer, a first guide pipe, a connecting pipe, a first electric push rod, a first connecting plate, a deflector rod and an elastic piece; a movable frame is arranged at the front part of the shell; the upper part of the movable frame is fixedly connected with a collecting box; the inside of the collecting box is connected with two drawers which are symmetrical left and right; the upper part of the collecting box is communicated with two first guide pipes which are symmetrical left and right; the front parts of the two first guide pipes are respectively communicated with a connecting pipe; the inner parts of the two connecting pipes are fixedly connected with a first electric push rod respectively; the two first electric push rods are respectively connected with one separating frame; a first connecting plate is fixedly connected between the two separation frames; the front parts of the two connecting pipes are respectively connected with a deflector rod in a sliding way; the two driving levers are respectively fixedly connected with an elastic piece; the two elastic pieces are respectively fixedly connected with a connecting pipe.

More preferably, the cleaning assembly comprises a fixed pipe, a first fixed frame, a first motor, a first telescopic column, a first connecting frame, a second electric push rod, a brush plate, a second connecting plate, an annular slide rail, a screw rod, a second connecting frame, a third electric push rod, a first bearing seat, a telescopic plate, a second bearing seat and a hook; a fixed pipe is communicated between the two connecting pipes; the inner part of the fixed tube is fixedly connected with a first fixed frame; the rear part of the first fixing frame is fixedly connected with a first motor; the output shaft of the first motor is fixedly connected with a first telescopic column; the first telescopic column is rotatably connected with the fixed pipe; the front part of the first telescopic column is fixedly connected with a first connecting frame; the front part of the first connecting frame is fixedly connected with the connecting cylinder; the outer surface of the connecting cylinder is fixedly connected with six brush plates which are distributed at equal intervals; the front part of the first fixing frame is fixedly connected with two bilaterally symmetrical second electric push rods; the telescopic ends of the two second electric push rods are respectively and fixedly connected with a second connecting plate; an annular slide rail is fixedly connected between the two second connecting plates; the annular slide rail is connected with the connecting cylinder in a sliding manner; a screw rod is rotatably connected inside the connecting cylinder; the screw rod is screwed with the elastic plug; the front part of the screw rod is fixedly connected with a second connecting frame; the second connecting frame is fixedly connected with the plugging ring; the front part of the second connecting frame is fixedly connected with a third electric push rod; the telescopic end of the third electric push rod is fixedly connected with a first bearing seat; the front part of the first bearing seat is rotationally connected with four annular array expansion plates through a rotating shaft; the front parts of the four expansion plates are respectively connected with a second bearing seat in a rotating way through rotating shafts; the front parts of the four expansion plates are respectively fixedly connected with a hook; and the four second bearing seats are fixedly connected with the plugging ring.

More preferably, the winding assembly comprises a guide assembly, a first flow guide pipe, a second telescopic column and a third connecting plate; the front part of the shell is connected with a guide component; the inner bottom of the shell is fixedly connected with four second telescopic columns; the inner upper part of the shell is fixedly connected with another two second telescopic columns; the six second telescopic columns are divided into a group, and the upper parts of the six second telescopic columns are fixedly connected with a third connecting plate respectively; the six third connecting plates are in a group of two, and another guide assembly is connected between every two third connecting plates; the three guide assemblies are connected with a first guide pipe in a sliding mode.

More preferably, the guiding component connected to the housing comprises a first fixed block, a first guiding roller, a second fixed block and a second guiding roller; the shell is connected with two first fixed blocks which are bilaterally symmetrical; the shell is connected with two second fixed blocks which are bilaterally symmetrical; a second guide roller is rotatably connected between the two first fixed blocks; another second guide roller is rotatably connected between the two second fixed blocks; a first guide roller is connected between the first fixed block and the second fixed block on the same side in a co-rotating mode.

More preferably, the filtering assembly comprises a second fixing frame, a third fixing frame, a pump, a second guide pipe, a shell, a fourth connecting plate, a second motor, a third guide pipe, an air guide pipe, a second guide pipe, a connecting roller, a first connecting rod, a connecting ring and a telescopic rod; a second fixing frame is fixedly connected inside the shell; the right part of the shell is fixedly connected with a third fixing frame; a pump is fixedly connected inside the third fixing frame; the pump is communicated with the first flow guide pipe; the upper part of the second fixing frame is fixedly connected with a second guide tube; the front part of the second guide tube is fixedly connected with a fourth connecting plate; a third guide tube is fixedly connected inside the shell; the third guide tube is fixedly connected with the second fixing frame; the upper part of the third guide tube is fixedly connected with another fourth connecting plate; a shell is fixedly connected to the two fourth connecting plates together; the two fourth connecting plates are in sliding connection with the filter cartridges; the rear part of the fourth connecting plate positioned at the rear part is fixedly connected with a second motor; the output end of the second motor is fixedly connected with a connecting roller; the outer surface of the connecting roller is fixedly connected with a plurality of first connecting rods in annular array; the plurality of first connecting rods are respectively and rotatably connected with one second connecting rod through a rotating shaft; the outer surfaces of the second connecting rods are fixedly connected with six connecting rings which are distributed at equal intervals; the outer surface of the connecting roller is fixedly connected with a plurality of fifth connecting plates; four telescopic rods are connected to the fifth connecting plates in a sliding manner; the lower part of the shell is fixedly connected with two air guide tubes which are symmetrical left and right; the two air ducts penetrate through the shell; the fourth connecting plate positioned in front is communicated with a second flow guide pipe; the second honeycomb duct is arranged through the shell.

A soil pick-up process for biologically treating waste comprising the steps of:

s1: the dirt of the motor car is flushed and smashed from the pool under high pressure, and the dirt is led out from the accumulation pool on the vacuum dirt collection closestool by using a vacuum pump;

s2: sewage suction and reverse transportation, wherein sewage led out from the vacuum sewage collection closestool is sucked into a septic tank by using a sewage pump, blockage in a sewage discharge pipeline of the motor car is dredged by a cleaning assembly, and a blockage generated in the sewage suction process is cleaned in a negative pressure mode, so that the sewage suction efficiency is improved;

s3: separating liquid dung, separating the liquid dung in a filtering mode, separating the liquid dung through a filtering assembly, switching the surface of a filter screen in a shifting mode continuously, dredging the liquid dung blocking the filter screen in a pushing mode, and further improving the filtering efficiency;

s4: ventilating and illuminating the tank, illuminating and observing the filtering condition of the septic tank, and ventilating to reduce the concentration of ammonia nitrogen and methane in the septic tank;

s5: detecting harmful gas in the pool, namely detecting the concentrations of ammonia nitrogen gas and methane in the septic tank;

s6: cleaning the bottom of the artificial pond, and manually cleaning excrement remained at the bottom of the septic tank;

s7: the method comprises the following steps of (1) treating the wastewater, namely reducing the concentration of ammonia nitrogen gas in the wastewater by adopting a blow-off method, reducing the concentration of the ammonia nitrogen gas in the wastewater by using a filtering assembly, reducing the concentration of ammonia nitrogen gas in the wastewater by adopting the blow-off method, breaking foam generated by the blow-off method, and enhancing the effect of reducing the concentration of the ammonia nitrogen gas by the blow-off method;

s8: the dried substances are synthesized into organic fertilizer, and the solid filtered from the excrement and the like is synthesized into the organic fertilizer.

Advantageous effects

1. The cleaning device realizes the cleaning of the liquid dung in the toilet of the motor car, dredges the blockage in the blow-off pipeline of the motor car by adopting a negative pressure mode, dredges the blockage by adopting a sealing mode, avoids the blockage and the liquid dung in the blow-off pipeline from flowing into the motor car track and the mechanical parts of the motor car in the dredging process, and avoids the liquid dung from being remained on the track for a long time to corrode the track and the mechanical parts of the motor car;

2. the filter screen is adopted to separate liquid dung, the filter cartridge is shifted to rotate, the filter surface is switched, and filter matters in the filter cartridge cannot be accumulated at one position, so that the filter cartridge is different from the conventional standing filter mode, the filtering efficiency is improved, meanwhile, the blockage of the filter cartridge is dredged, and the possibility of blockage of the filter cartridge is reduced;

3. the blowing-off method is adopted to reduce the concentration of ammonia nitrogen gas in the sewage, and simultaneously, the foam generated by the blowing-off method is broken, so that the blowing-off effect is enhanced.

Drawings

FIG. 1 is a schematic view of a first construction of a soil pick-up device for biologically treating waste according to the present invention;

FIG. 2 is a schematic view of a second construction of a soil pick-up device for biologically treating waste according to the present invention;

FIG. 3 is a schematic view of a first construction of a collection assembly of a soil pick-up device for biologically treating waste in accordance with the present invention;

FIG. 4 is a schematic view of a second construction of a collection assembly of a soil pick-up device for biologically treating waste according to the present invention;

FIG. 5 is a schematic view of a portion of the collecting unit of the soil pick-up device for biologically treating waste according to the present invention;

FIG. 6 is a schematic view of a cleaning assembly of the soil pick-up device for biologically treating waste according to the present invention;

FIG. 7 is a schematic view of a portion of a cleaning assembly of a soil pick-up device for biologically treating waste according to the present invention;

FIG. 8 is a schematic view of the reel assembly of the soil pick-up device for biologically treating waste according to the present invention;

FIG. 9 is a schematic view of a first construction of a filter assembly of a soil pick-up device for biologically treating waste in accordance with the present invention;

FIG. 10 is a schematic view of a second construction of a filter assembly of a soil pick-up device for biologically treating waste in accordance with the present invention;

FIG. 11 is a schematic view of a first partial configuration of a filter assembly of a soil pick-up device for biologically treating waste in accordance with the present invention;

FIG. 12 is a second partial schematic view of a filter assembly of a soil pick-up device for biologically treating waste in accordance with the present invention.

Part names and serial numbers in the figure: 1-housing, 2-collecting component, 3-cleaning component, 4-rolling component, 5-filtering component, 201-moving rack, 202-collecting box, 203-drawer, 204-first guide tube, 205-connecting tube, 206-first electric push rod, 207-separating frame, 209-first connecting plate, 2010-deflector rod, 2011-elastic component, 301-fixing tube, 302-first fixing rack, 303-first motor, 304-first telescopic column, 305-first connecting rack, 306-second electric push rod, 307-connecting barrel, 307 a-chute, 308-brush plate, 309-second connecting plate, 3010-annular slide rail, 3011-blocking ring, 3012-lead screw, 3013-elastic plug, 3014-second connecting rack, 3015-third electric push rod, 3016-first bearing block, 3017-expansion plate, 3018-second bearing block, 3019-hook, 401-first fixed block, 402-first guide roller, 403-second fixed block, 404-second guide roller, 405-first guide tube, 406-second expansion column, 407-third connecting plate, 501-second fixed frame, 502-third fixed frame, 503-pump machine, 504-second guide tube, 505-shell, 506-fourth connecting plate, 507-second motor, 508-filter cylinder, 509-third guide tube, 5010-air guide tube, 5011-second guide tube, 5012-connecting roller, 5013-first connecting rod, 5014-second connecting rod, 5014 a-extrusion block, 5015-501, 5016-fifth connecting plate, 5017-telescopic rod.

Detailed description of the preferred embodiments

The preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Examples

A soil pick-up device for biologically treating waste, as shown in fig. 1-12, comprises a housing 1, a collection assembly 2, a separation frame 207, a first connecting plate 209, a cleaning assembly 3, a connecting cylinder 307, a plugging ring 3011, an elastic plug 3013, a rolling assembly 4, a filter assembly 5, a filter cartridge 508, a second connecting rod 5014 and a fifth connecting plate 5016; the front part of the shell 1 is provided with a collecting component 2; two bilaterally symmetrical separating frames 207 are connected to the collecting assembly 2; the shell 1 is connected with a cleaning component 3; the collecting component 2 is connected with the cleaning component 3; the interior of the cleaning component 3 is connected with a connecting cylinder 307; an elastic plug 3013 is slidably connected to the inside of the connecting cylinder 307; a plugging ring 3011 is connected in the cleaning component 3; a winding component 4 is connected inside the shell 1; the cleaning component 3 is connected with the winding component 4; a filter assembly 5 is connected inside the shell 1; the winding component 4 is connected with the filtering component 5; a filter cartridge 508 is connected to the filter assembly 5; the filtering component 5 is connected with a plurality of second connecting rods 5014; a plurality of fifth connection plates 5016 are connected to the filter assembly 5.

The inner wall of the connecting cylinder 307 is provided with four annular arrays of sliding grooves 307a.

The plugging ring 3011 is of a rubber structure and has elasticity.

The second connecting rod 5014 is provided with an inverted conical pressing block 5014a.

The collecting assembly 2 comprises a moving frame 201, a collecting box 202, a drawer 203, a first guide pipe 204, a connecting pipe 205, a first electric push rod 206, a first connecting plate 209, a deflector rod 2010 and an elastic piece 2011; a movable frame 201 is arranged at the front part of the shell 1; the upper part of the movable frame 201 is fixedly connected with a collecting box 202; the inside of the collecting box 202 is connected with two drawers 203 which are symmetrical left and right; the upper part of the collecting box 202 is communicated with two first guide pipes 204 which are symmetrical left and right; the front parts of the two first guide tubes 204 are respectively communicated with a connecting tube 205; a first electric push rod 206 is fixedly connected inside each of the two connecting pipes 205; the two first electric push rods 206 are respectively connected with a separation frame 207; a first connecting plate 209 is fixedly connected between the two separation frames 207; the front parts of the two connecting pipes 205 are respectively connected with a driving lever 2010 in a sliding way; an elastic piece 2011 is fixedly connected to each of the two driving levers 2010; the two elastic members 2011 are fixedly connected to one connecting tube 205.

The cleaning assembly 3 comprises a fixed pipe 301, a first fixed frame 302, a first motor 303, a first telescopic column 304, a first connecting frame 305, a second electric push rod 306, a brush plate 308, a second connecting plate 309, an annular slide rail 3010, a screw rod 3012, a second connecting frame 3014, a third electric push rod 3015, a first bearing seat 3016, a telescopic plate 3017, a second bearing seat 3018 and a hook 3019; a fixed pipe 301 is communicated between the two connecting pipes 205; a first fixing frame 302 is fixedly connected inside the fixing tube 301; the rear part of the first fixing frame 302 is connected with a first motor 303 through bolts; the output shaft of the first motor 303 is fixedly connected with a first telescopic column 304; the first telescopic column 304 is rotatably connected with the fixed pipe 301; a first connecting frame 305 is fixedly connected to the front part of the first telescopic column 304; the front part of the first connecting frame 305 is fixedly connected with the connecting cylinder 307; the outer surface of the connecting cylinder 307 is fixedly connected with six brush plates 308 which are distributed at equal intervals; two bilaterally symmetrical second electric push rods 306 are fixedly connected to the front part of the first fixing frame 302; the telescopic ends of the two second electric push rods 306 are fixedly connected with a second connecting plate 309 respectively; an annular sliding rail 3010 is fixedly connected between the two second connecting plates 309; the annular slide rail 3010 is connected with the connecting cylinder 307 in a sliding manner; a screw rod 3012 is rotatably connected to the inside of the connecting cylinder 307; the screw rod 3012 is screwed with the elastic plug 3013; the front part of the screw rod 3012 is fixedly connected with a second connecting frame 3014; the second connecting frame 3014 is fixedly connected with the plugging ring 3011; the front part of the second connecting frame 3014 is fixedly connected with a third electric push rod 3015; the telescopic end of the third electric push rod 3015 is fixedly connected with a first bearing seat 3016; the front part of the first bearing block 3016 is rotatably connected with four annular array expansion plates 3017 through a rotating shaft; the front parts of the four telescopic plates 3017 are respectively connected with a second bearing block 3018 through a rotating shaft; the front parts of the four telescopic plates 3017 are fixedly connected with hooks 3019 respectively; and the four second bearing seats 3018 are fixedly connected with the plugging ring 3011.

The winding component 4 comprises a guide component, a first guide pipe 405, a second telescopic column 406 and a third connecting plate 407; a guide assembly is connected to the front part of the shell 1; four second telescopic columns 406 are fixedly connected to the inner bottom of the shell 1; the inner upper part of the shell 1 is fixedly connected with another two second telescopic columns 406; two of the six second telescopic columns 406 form a group, and the upper parts of the six second telescopic columns 406 are fixedly connected with a third connecting plate 407 respectively; two of the six third connecting plates 407 form a group, and another guiding component is connected between every two third connecting plates 407; a first duct 405 is slidably connected to the three guide members.

The guiding component connected to the housing 1 comprises a first fixed block 401, a first guiding roller 402, a second fixed block 403 and a second guiding roller 404; two first fixed blocks 401 which are symmetrical left and right are connected to the shell 1; two second fixed blocks 403 which are symmetrical left and right are connected to the shell 1; a second guide roller 404 is rotatably connected between the two first fixed blocks 401; another second guide roller 404 is rotatably connected between the two second fixed blocks 403; a first guide roller 402 is connected between the first fixing block 401 and the second fixing block 403 on the same side in a co-rotating manner.

The filter assembly 5 comprises a second fixing frame 501, a third fixing frame 502, a pump 503, a second guide pipe 504, a shell 505, a fourth connecting plate 506, a second motor 507, a third guide pipe 509, an air duct 5010, a second guide pipe 5011, a connecting roller 5012, a first connecting rod 5013, a connecting ring 5015 and a telescopic rod 5017; a second fixing frame 501 is fixedly connected inside the shell 1; a third fixing frame 502 is fixedly connected to the right part of the shell 1; the interior of the third fixing frame 502 is bolted with a pump 503; the pump 503 is communicated with the first draft tube 405; a second guide tube 504 is fixedly connected to the upper part of the second fixing frame 501; a fourth connecting plate 506 is fixedly connected to the front part of the second guide tube 504; a third guide tube 509 is fixedly connected to the inside of the housing 1; the third guiding tube 509 is fixedly connected with the second fixing frame 501; the upper part of the third guiding tube 509 is fixedly connected with another fourth connecting plate 506; a shell 505 is fixedly connected to the two fourth connecting plates 506; the two fourth connecting plates 506 are connected with the filter cylinder 508 in a sliding way; a second motor 507 is connected to the rear part of the fourth connecting plate 506 positioned at the rear part through bolts; the output end of the second motor 507 is fixedly connected with a connecting roller 5012; the outer surface of the connecting roller 5012 is fixedly connected with a plurality of first connecting rods 5013 which are annularly arrayed; the plurality of first connecting rods 5013 are respectively and rotatably connected with one second connecting rod 5014 through rotating shafts; the outer surfaces of the second connecting rods 5014 are fixedly connected with six connecting rings 5015 which are distributed equidistantly; the outer surface of the connecting roller 5012 is fixedly connected with a plurality of fifth connecting plates 5016; the fifth connecting plates 5016 are respectively connected with four telescopic rods 5017 in a sliding manner; the lower part of the shell 505 is fixedly connected with two bilaterally symmetrical air ducts 5010; the two air ducts 5010 penetrate through the shell 1; the fourth connecting plate 506 positioned in front is communicated with a second draft tube 5011; the second flow guide pipe 5011 penetrates through the housing 1.

The outer surface of the attachment ring 5015 is provided with a plurality of annular arrays of lancets.

A soil pick-up process for biologically treating waste comprising the steps of:

s2: sewage suction and reverse transportation, wherein sewage led out from the vacuum sewage collection closestool is sucked into the septic tank by using a sewage pump, blockage in a sewage discharge pipeline of the motor car is dredged by the cleaning assembly 3, and blockage generated in the sewage suction process is cleaned in a negative pressure mode, so that the sewage suction efficiency is improved;

s3: separating liquid dung, separating the liquid dung in a filtering mode, separating the liquid dung through a filtering component 5, switching the surface of a filter screen in a shifting mode continuously, dredging the liquid dung blocking the filter screen in a pushing mode, and further improving the filtering efficiency;

s7: the method comprises the following steps of (1) treating the wastewater, namely reducing the concentration of ammonia nitrogen gas in the wastewater by adopting a blow-off method, reducing the concentration of the ammonia nitrogen gas in the wastewater by using a filtering assembly 5, reducing the concentration of the ammonia nitrogen gas in the wastewater by adopting the blow-off method, breaking foam generated by the blow-off method, and enhancing the effect of reducing the concentration of the ammonia nitrogen gas by the blow-off method;

Firstly, a worker fixes a sewage suction device for biologically treating wastes at a position to be used, then controls the sewage suction device for biologically treating wastes to operate and debug, then pushes the collection box 202 to move forward under the driving of the moving frame 201 to be close to a sewage discharge port of a bullet train, the collection box 202 drives components connected with the collection box to move forward, namely, the collection box drives the drawer 203, the first guide pipe 204, the connecting pipe 205, the first electric push rod 206, the separation frame 207, the first connecting plate 209, the shift lever 2010 and the elastic piece 2011 to move forward, meanwhile, the two connecting pipes 205 drive the fixed pipe 301 to move forward to be close to the sewage discharge port of the bullet train, simultaneously pulls the first guide pipe 405, guides the components forward under the action of the first guide roller 402 and the second guide roller 404, simultaneously stretches the second telescopic column 406 positioned below, simultaneously drives the third connecting plate 407 connected with the fixed pipe 301 to move along with the sewage discharge port of the bullet train, and then, and the fixed pipe 301 is butted and fixed with the sewage discharge port of the bullet train; then the pump 503 is controlled to lead out the liquid dung, the garbage and the like flowing out of the sewage outlet through the fixed pipe 301 and the first guide pipe 405, and the liquid dung, the garbage and the like enter the filter cylinder 508 through the second guide pipe 504; when a drain outlet of the bullet train is blocked, the two second electric push rods 306 are controlled to push the two second connecting plates 309 to move forwards, the two second connecting plates 309 drive the annular slide rails 3010 to move forwards, the annular slide rails 3010 drive the connecting cylinder 307 to move forwards and enter the drain outlet of the bullet train, the connecting cylinder 307 drives the first connecting frame 305 to move along with the annular slide rails, and the first telescopic column 304 is stretched, the connecting cylinder 307 drives the components connected with the connecting cylinder to move along with the annular slide rails, namely the brush plate 308, the blocking ring 3011, the lead screw 3012, the elastic plug 3013, the second connecting frame 3014, the third electric push rod 3015, the first bearing 3016, the telescopic plate 3017, the second bearing 3018 and the hook 3019 to move along with the annular slide rails, so that the blocking ring 3011 enters the drain outlet of the bullet train, then the third electric push rod 3015 is controlled to push the first bearing 3016 to move forwards, the first bearing 3016 drives the other end of the telescopic plate 3017 to move forwards, so that the telescopic plate 3017 is under the limiting effect of the second bearing 3018, the expansion plate 3017 rotates around a rotating shaft on the second bearing seat 3018, the expansion plate 3017 is compressed at the same time, the expansion plate 3017 pushes the front end of the plugging ring 3011 to expand outwards, and at the same time, under the elastic action of the plugging ring 3011, the front end of the plugging ring 3011 is made to adhere to the inner wall of the sewage pipe, then the first motor 303 is controlled to drive the first expansion column 304 to rotate, the first expansion column 304 drives the first connecting frame 305 to rotate, the first connecting frame 305 drives the connecting cylinder 307 to slide in the annular sliding rail 3010, in this process, the connecting cylinder 307 drives the brush plate 308 to rotate to clean the inside of the sewage pipe, the connecting cylinder 307 drives the elastic plug 3013 to rotate, but under the limiting action of the chute 307a formed in the connecting cylinder 307 and the screw rod 3012, the elastic plug 3013 is forced to slide backwards in the connecting cylinder 307, so that the air in the space formed by the plugging ring 3011 and the plugged sewage outlet enters the expanding space of the connecting cylinder 307, the method comprises the steps of enabling a blockage of a blocked sewage discharge port to approach a blocking ring 3011 under the action of negative pressure, then controlling a third electric push rod 3015 to contract to enable the blocking ring 3011 to contract, then controlling a first motor 303 to drive an elastic plug 3013 to reset, then enabling the blockage to further approach the blocking ring 3011 in the same operation mode, then operating for multiple times to enable the blockage to be attached to the blocking ring 3011, then controlling the third electric push rod 3015 to drive an expansion plate 3017 to reset, meanwhile driving a hook 3019 to limit the blockage, then controlling two second electric push rods 306 to contract, meanwhile driving the blockage to enter a fixed tube 301, enabling the blockage to move into a separation frame 207, then controlling two first electric push rods 206 to contract and stretch simultaneously, namely controlling a first electric push rod 206 located on the right to push the separation frame 207 to move leftwards, controlling the first electric push rod 206 located on the left to contract to pull another separation frame 207 to move leftwards, namely driving the blockage to move leftwards to be located right of a first guide tube 204 located on the left, then a worker pushes a deflector rod 2010, and compresses an elastic piece to push a deflector rod 2010 to enter a first guide tube 202, so that the blockage enters a first guide tube 204, and a first guide tube 204 to pass through a collecting box 204, and a deflector rod 203.

The dredged sewage outlet drives the liquid dung mixture to enter a filter cylinder 508 through a fixed pipe 301 and a first guide pipe 405, meanwhile, the water of the liquid dung mixture is filtered through the filter cylinder 508 and enters a space formed by a shell 505 and a fourth connecting plate 506, in the process, a second motor 507 is controlled to drive a connecting roller 5012 to rotate, the connecting roller 5012 drives components connected with the connecting roller to rotate along with the connecting roller 5012, namely, the first connecting rod 5013, the second connecting rod 5014, a connecting ring 5015, a fifth connecting plate 5016 and a telescopic rod 5017 are driven to rotate along with the connecting roller, so that an extrusion block 5014a is contacted with the filter cylinder 508, meanwhile, under the limiting action of the filter cylinder 508, the second connecting rod 5014 rotates by taking a rotating shaft on the first connecting rod 5013 as a rotating center, when the second connecting rod 5014 rotates to the limit, in the further rotating process, the filter cylinder 508 is shifted to slide in arc-shaped tracks arranged on the two fourth connecting plates 506, meanwhile, the fifth connecting plate 5016 drives the telescopic rod 5017 to be attached to the filter cylinder 508 to rotate, when the telescopic rod 5017 contacts the filter screen on the filter cylinder 508 and extrudes the telescopic rod 5017 under the limiting effect of the filter screen on the filter cylinder 508, so that the telescopic rod 5017 enters the fifth connecting plate 5016, when the telescopic rod 5017 moves to a filter hole on the filter cylinder 508, the compressed telescopic rod 5017 resets to push a blockage in the filter hole to avoid the filter cylinder 508 from being blocked, in the process, air is introduced into the two air guide pipes 5010 by using an external air pump, the concentration of ammonia nitrogen gas in the filtered wastewater is reduced by adopting a blowing-off method, in the process, excessive foam is generated in the wastewater, the blowing-off effect is influenced by the generation of the foam, in the process, a prick part of the foam by the prick on the rotating connecting ring 5015, the generation of the foam is reduced, and the blowing-off effect is further enhanced.

The above embodiments are merely illustrative of the technical ideas and features of the present invention, and the purpose thereof is to enable those skilled in the art to understand the contents of the present invention and implement the present invention, and not to limit the protection scope of the present invention. All equivalent changes and modifications made according to the spirit of the present invention should be covered within the protection scope of the present invention.

Claims

1. A soil pick-up device for biologically treating waste, comprising a housing (1); the method is characterized in that: the device also comprises a collecting component (2), a separating frame (207), a first connecting plate (209), a cleaning component (3), a connecting cylinder (307), a plugging ring (3011), an elastic plug (3013), a rolling component (4), a filtering component (5), a filtering cylinder (508), a second connecting rod (5014) and a fifth connecting plate (5016); a collecting component (2) is arranged at the front part of the shell (1); two separation frames (207) which are bilaterally symmetrical and used for separating the blockage are connected to the collecting assembly (2); the shell (1) is connected with a cleaning component (3); the collecting component (2) is connected with the cleaning component (3); the interior of the cleaning component (3) is connected with a connecting cylinder (307); an elastic plug (3013) is connected in a sliding manner inside the connecting cylinder (307); a plugging ring (3011) for sealing the sewage discharge pipe is connected in the cleaning component (3); a winding component (4) is connected inside the shell (1); the cleaning component (3) is connected with the winding component (4); a filtering component (5) is connected inside the shell (1); the winding component (4) is connected with the filtering component (5); a filter cylinder (508) for separating liquid dung is connected to the filter component (5); the filter component (5) is connected with a plurality of second connecting rods (5014) used for shifting the filter cartridges (508); the filter assembly (5) is connected with a plurality of fifth connecting plates (5016) used for scraping the blockage on the filter cylinder (508);

the collecting assembly (2) comprises a moving frame (201), a collecting box (202), a drawer (203), a first guide pipe (204), a connecting pipe (205), a first electric push rod (206), a first connecting plate (209), a shifting lever (2010) and an elastic piece (2011); a movable frame (201) is arranged at the front part of the shell (1); the upper part of the movable frame (201) is fixedly connected with a collecting box (202); two drawers (203) which are symmetrical left and right are connected inside the collecting box (202); the upper part of the collecting box (202) is communicated with two first guide pipes (204) which are symmetrical left and right; the front parts of the two first guide pipes (204) are respectively communicated with a connecting pipe (205); a first electric push rod (206) is fixedly connected inside each of the two connecting pipes (205); the two first electric push rods (206) are respectively connected with a separation frame (207); a first connecting plate (209) is fixedly connected between the two separation frames (207); the front parts of the two connecting pipes (205) are respectively connected with a deflector rod (2010) in a sliding way; an elastic piece (2011) is fixedly connected to each of the two shift levers (2010); pushing the deflector rod (2010) and compressing the elastic piece (2011), wherein the deflector rod (2010) pushes the blockage into the first guide tube (204); the two elastic pieces (2011) are respectively and fixedly connected with one connecting pipe (205);

the cleaning assembly (3) comprises a fixed pipe (301), a first fixing frame (302), a first motor (303), a first telescopic column (304), a first connecting frame (305), a second electric push rod (306), a brush plate (308), a second connecting plate (309), an annular sliding rail (3010), a screw rod (3012), a second connecting frame (3014), a third electric push rod (3015), a first bearing seat (3016), a telescopic plate (3017), a second bearing seat (3018) and a hook (3019); a fixed pipe (301) is communicated between the two connecting pipes (205); a first fixing frame (302) is fixedly connected inside the fixing tube (301); the rear part of the first fixing frame (302) is fixedly connected with a first motor (303); the output shaft of the first motor (303) is fixedly connected with a first telescopic column (304); the first telescopic column (304) is rotatably connected with the fixed pipe (301); the front part of the first telescopic column (304) is fixedly connected with a first connecting frame (305); the front part of the first connecting frame (305) is fixedly connected with the connecting cylinder (307); the outer surface of the connecting cylinder (307) is fixedly connected with six brush plates (308) which are distributed at equal intervals; the front part of the first fixing frame (302) is fixedly connected with two bilaterally symmetrical second electric push rods (306); the telescopic ends of the two second electric push rods (306) are respectively and fixedly connected with a second connecting plate (309); an annular sliding rail (3010) is fixedly connected between the two second connecting plates (309); the annular sliding rail (3010) is connected with the connecting cylinder (307) in a sliding way; a screw rod (3012) is rotatably connected to the inside of the connecting cylinder (307); the screw rod (3012) is screwed with the elastic plug (3013); the front part of the screw rod (3012) is fixedly connected with a second connecting frame (3014); the second connecting frame (3014) is fixedly connected with the plugging ring (3011); the front part of the second connecting frame (3014) is fixedly connected with a third electric push rod (3015); the telescopic end of the third electric push rod (3015) is fixedly connected with a first bearing seat (3016); the front part of the first bearing block (3016) is rotatably connected with four annular array telescopic plates (3017) through a rotating shaft; the front parts of the four telescopic plates (3017) are respectively connected with a second bearing seat (3018) in a rotating way through a rotating shaft; the front parts of the four expansion plates (3017) are respectively fixedly connected with a hook (3019); the four second bearing seats (3018) are fixedly connected with the plugging ring (3011);

the inner wall of the connecting cylinder (307) is provided with four annular-array sliding grooves (307 a);

the plugging ring (3011) is of a rubber structure and has elasticity.

2. A soil pick-up device for biologically treating waste according to claim 1 wherein: the second connecting rod (5014) is provided with an inverted conical extrusion block (5014 a).

3. A soil pick-up device for biologically treating waste according to claim 2 wherein: the winding component (4) comprises a guide component, a first guide pipe (405), a second telescopic column (406) and a third connecting plate (407); the front part of the shell (1) is connected with a guide component; the inner bottom of the shell (1) is fixedly connected with four second telescopic columns (406); the inner upper part of the shell (1) is fixedly connected with another two second telescopic columns (406); two of the six second telescopic columns (406) form a group, and the upper parts of the six second telescopic columns (406) are fixedly connected with a third connecting plate (407) respectively; two third connecting plates (407) are used as a group, and another guide assembly is connected between every two third connecting plates (407); a first flow guide tube (405) is slidably connected to the three guide assemblies.

4. A soil pick-up device for biologically treating waste according to claim 3 wherein: the guide assembly connected to the shell (1) comprises a first fixed block (401), a first guide roller (402), a second fixed block (403) and a second guide roller (404); the shell (1) is connected with two first fixed blocks (401) which are symmetrical left and right; two second fixed blocks (403) which are symmetrical left and right are connected to the shell (1); a second guide roller (404) is rotatably connected between the two first fixed blocks (401); another second guide roller (404) is rotatably connected between the two second fixed blocks (403); a first guide roller (402) is connected between the first fixed block (401) and the second fixed block (403) on the same side in a co-rotating mode.

5. A soil pick-up device for the biological treatment of waste as claimed in claim 4 wherein: the filtering component (5) comprises a second fixing frame (501), a third fixing frame (502), a pump (503), a second guide pipe (504), a shell (505), a fourth connecting plate (506), a second motor (507), a third guide pipe (509), an air guide pipe (5010), a second guide pipe (5011), connecting rollers (5012), a first connecting rod (5013), a connecting ring (5015) and a telescopic rod (5017); a second fixing frame (501) is fixedly connected inside the shell (1); a third fixing frame (502) is fixedly connected to the right part of the shell (1); a pump (503) is fixedly connected inside the third fixing frame (502); the pump (503) is communicated with the first guide pipe (405); a second guide tube (504) is fixedly connected to the upper part of the second fixing frame (501); a fourth connecting plate (506) is fixedly connected to the front part of the second guide tube (504); a third guide tube (509) is fixedly connected inside the shell (1); the third guide tube (509) is fixedly connected with the second fixing frame (501); the upper part of the third guide tube (509) is fixedly connected with another fourth connecting plate (506); a shell (505) is fixedly connected to the two fourth connecting plates (506) together; the two fourth connecting plates (506) are in sliding connection with the filter cylinder (508); the rear part of the fourth connecting plate (506) positioned at the rear part is fixedly connected with a second motor (507); the output end of the second motor (507) is fixedly connected with a connecting roller (5012); the outer surface of the connecting roller (5012) is fixedly connected with a plurality of first connecting rods (5013) in annular arrays; the plurality of first connecting rods (5013) are respectively and rotatably connected with one second connecting rod (5014) through rotating shafts; the outer surfaces of the second connecting rods (5014) are fixedly connected with six connecting rings (5015) which are distributed at equal intervals; the outer surface of the connecting roller (5012) is fixedly connected with a plurality of fifth connecting plates (5016); the fifth connecting plates (5016) are respectively connected with four telescopic rods (5017) in a sliding manner; the lower part of the shell (505) is fixedly connected with two air ducts (5010) which are symmetrical left and right; the two air guide pipes (5010) penetrate through the shell (1); the fourth connecting plate (506) positioned in front is communicated with a second flow guide pipe (5011); the second guide pipe (5011) penetrates through the shell (1).

6. A soil pick-up process for biologically treating waste, characterized by: use of a soil pick-up device for the biological treatment of waste as claimed in claim 5, comprising the steps of:

s1: the dirt of the motor car is flushed and smashed from the pool at high pressure, and the dirt is led out from the accumulation pool on the vacuum dirt collection closestool by using a vacuum pump;

s2: sewage suction and reverse transportation, wherein sewage led out from the vacuum sewage collection closestool is sucked into the septic tank by using a sewage pump, blockage in a sewage discharge pipeline of the motor car is dredged by the cleaning assembly (3), and blockage generated in the sewage suction process is cleaned in a negative pressure mode, so that the sewage suction efficiency is improved;

s3: separating liquid and excrement, then separating the liquid and excrement in a filtering mode, separating the liquid and excrement through a filtering component (5), switching the surface of a filter screen continuously in a shifting mode, dredging the excrement blocking the filter screen in a pushing mode, and further improving the filtering efficiency;

s7: the wastewater is treated, the concentration of ammonia nitrogen in the wastewater is reduced by adopting a blow-off method, the concentration of the ammonia nitrogen in the wastewater is reduced by a filtering assembly (5), the concentration of ammonia nitrogen in the wastewater is reduced by adopting the blow-off method, foams generated by the blow-off method are broken, and the effect of reducing the concentration of the ammonia nitrogen by adopting the blow-off method is enhanced;

s8: the dried matter is synthesized into organic fertilizer, and the solid filtered from excrement and the like is synthesized into organic fertilizer.