CN116290275B - Can accelerate velocity of flow and recycle's dirty shunt tubes of rain - Google Patents

Abstract

The invention discloses a rain and sewage shunt tube capable of accelerating flow speed and recycling, and relates to the technical field of municipal administration. According to the invention, the first motor works, the driving gear can drive the driven gear to rotate, the split box can rotate through the first rotating seat and the second rotating seat due to the engagement of the split box and the driven gear, at the moment, sewage can flow into the inside of the split box through the filter screen layer under the action of centrifugal force by enabling the split box to rotate at a high speed, and the dirt can be blocked by the filter screen layer and stored in the inside of the split box, so that the separation speed of the sewage and the dirt can be greatly improved, and the influence on normal drainage of equipment due to the fact that the separation speed of the split box and the sewage is too slow can be avoided.

Description

Can accelerate velocity of flow and recycle's dirty shunt tubes of rain

Technical Field

The invention relates to the technical field of municipal administration, in particular to a rain and sewage shunt pipe capable of accelerating flow speed and recycling.

Background

Municipal administration refers to various administrative management works of cities, the administrative works of cities comprise industry, commerce, traffic, public security, religion, environment, sanitation, basic construction and the like, wherein urban drainage belongs to an important project in the basic construction of municipal administration, and through making urban drainage projects, the conditions of waterlogging disasters, blocked traffic by rainwater and the like in cities can be greatly reduced when urban rainfall or heavy rain is produced, and the rain and sewage shunt pipe is an important ring in the drainage pipeline, can separate rainwater and sewage, can recycle the rainwater, and can realize the maximum utilization of rainwater resources.

The common rain and sewage shunt tubes in the market usually adopt a filter screen filtering method to realize rain and sewage separation, but the integral separation speed of the filtering method is lower, and the rain and sewage shunt tubes can be well realized when the rainwater is smaller, but in heavy rain weather, the filtering method is very easy to cause the rainwater to be blocked in a pipeline due to the lower separation speed, so that the normal drainage condition of the city is affected.

Accordingly, in view of the above, research and improvement on the existing structure and the existing defects have been conducted, and a rain and sewage shunt tube capable of accelerating the flow rate and recycling is proposed.

Disclosure of Invention

The invention aims to provide a rain and sewage shunt pipe capable of accelerating the flow rate and recycling the rain and sewage shunt pipe so as to solve the problems in the background technology.

In order to achieve the above purpose, the present invention provides the following technical solutions: the utility model provides a can accelerate the rain sewage shunt tubes of velocity of flow and recycle, includes water inlet pipe, acceleration rate subassembly and reposition of redundant personnel case, the bottom outside of water inlet pipe is connected with the shunt tubes, acceleration rate subassembly settles in the bottom outside of shunt tubes, and the bottom outside of acceleration rate subassembly is settled there is the collecting pipe, the bottom outside of collecting pipe is settled there is communicating pipe, the outer end of communicating pipe is settled there is the shunt tubes, and the bottom end of communicating pipe is provided with first swivel mount, the bottom outside of first swivel mount is settled in the shunt tubes, the inboard middle-end of shunt tubes is provided with the filter screen layer, and the bottom outside of shunt tubes is settled there is the second swivel mount, the bottom outside of second swivel mount is connected with the blow off pipe, the top outside of shunt tubes is provided with driven gear, and driven gear's outer end is settled there is the driving gear, the inboard of shunt tubes is provided with automatically controlled push rod, and the output of automatically controlled push rod is connected with the displacement seat, the outer end of displacement seat is settled there is first scraper blade, the inboard of communicating pipe and the drain tube is settled there is the first scraper blade, and the motor of the right side of holding seat.

Further, acceleration rate subassembly includes first water storage tank, second water storage tank, water moves oar, first carousel, drive belt, second carousel, first broken oar and first breather pipe, the second water storage tank has been settled in the right part outside of first water storage tank, and the inside of second water storage tank is settled there is water to move the oar, the outer end of water moves the oar is settled there is first carousel, and the outside of first carousel is provided with drive belt, drive belt keeps away from first carousel one side and is provided with the second carousel, the output of second carousel is connected with first broken oar, settle between first water storage tank and the second water storage tank has first breather pipe.

Further, the water impeller drives the transmission belt to rotate through the first rotating disc, and the transmission belt drives the first crushing impeller to rotate through the second rotating disc.

Further, the first water storage tank is communicated with the second water storage tank through the first vent pipe, and the size and the volume of the first water storage tank are consistent with those of the second water storage tank.

Further, the shunt box and the filter screen layer are integrated, and the shunt box rotates through the first swivel mount and the second swivel mount.

Further, the first motor drives the driving gear to rotate, the driving gear is meshed with the driven gear, and the shunt box is fixedly connected with the driven gear.

Further, the first scraping plate is attached to the outer surface of the filter screen layer, and the second scraping plate is attached to the inner surface of the filter screen layer.

Further, the connecting seat is fixedly connected with the communicating pipe and the sewage draining pipe, and the connecting seat is fixedly connected with the second scraping plate.

Further, the outer end of shunt tank is connected with the drain pipe, and the end-to-end connection of drain pipe has the recovery case, the outer end of recovery case is provided with the second vent pipe, the outer end of blow off pipe is provided with the second motor, and the output of second motor is connected with the broken oar of second.

Further, the recycling bin is communicated with the sewage drain pipe through a second vent pipe, and the second crushing paddle is arranged inside the sewage drain pipe.

The invention provides a rain and sewage shunt pipe capable of accelerating the flow rate and recycling, which has the following beneficial effects: .

1. The valve at the left end of the shunt pipe is closed, so that sewage can enter the second water storage tank through the shunt pipe, the valve at the right end of the collecting pipe is also in a closed state, sewage can be temporarily stored in the second water storage tank, after the second water storage tank is full of sewage, the valve at the left end of the shunt pipe is opened, the valve at the right end of the shunt pipe is closed, sewage can be transferred into the first water storage tank, the valve at the right end of the collecting pipe is converted into an open state, the valve at the left end of the collecting pipe is converted into a closed state, the first water storage tank can store sewage, the second water storage tank can drain the stored sewage in the second water storage tank, therefore, the right end of the shunt pipe is in a closed state, suction force formed by vacuum generated by the second water storage tank due to drainage can be transferred into the first water storage tank through the first ventilation pipe, the first water storage tank is in a water storage state, the water flow rate in the water inlet pipe can be improved by adding vacuum suction force when the first water storage tank stores water, and the urban drainage pressure during heavy rain can be greatly relieved by improving the water flow rate, in addition, after the first water storage tank stores water, the shunt pipe and the collecting pipe are switched again, so that the suction force generated when the first water storage tank drains water can be transmitted into the second water storage tank, the equipment can continuously generate suction force to improve the water flow rate, the equipment can be improved in a simple water storage tank switching mode through the operation, the water flow rate improving mode of the equipment can be simplified, the equipment is buried underground normally, the failure rate of the equipment can be greatly reduced by arranging a simple water lifting mode, thereby improving the stability of the device in use.

2. In the process of discharging water flow from the inside of the second water storage tank, the water impeller can be driven to rotate, the first rotary table can drive the transmission belt to rotate through the first rotary table in the process of rotating, the second rotary table can drive the first crushing impeller to rotate in the process of rotating, the first crushing impeller is positioned at the inner side of the first water storage tank, impurities which have larger inner volume and are clamped in the first water storage tank can be crushed through rotating the first crushing impeller, the impurities can be prevented from blocking the first water storage tank to affect normal use of the first water storage tank, the impurities can be crushed through enabling the first crushing impeller to be positioned at the time of water inlet of the first water storage tank, the normal use of the first crushing impeller can be prevented from being influenced by excessive water, meanwhile, the first crushing impeller can be enabled to sufficiently stir the water inlet sewage uniformly so as to facilitate the subsequent rainwater and sewage separation step, and the rotation of the first crushing impeller is realized through water drainage of the second water storage tank, so that the driving of the first crushing impeller does not need an extra power source, and the use and manufacturing cost of equipment can be reduced.

3. According to the invention, the driven gear is driven to rotate by the driving gear to work through the first motor, the shunt box is connected with the driven gear, so that the shunt box can rotate through the first rotary seat and the second rotary seat, at the moment, sewage can flow into the shunt box through the filter screen layer under the action of centrifugal force by enabling the shunt box to rotate at a high speed, the sewage can be blocked and stored in the shunt box by the filter screen layer, the separation speed of the sewage and the sewage can be improved by enabling the sewage and the sewage to be separated through the centrifugal force, the normal drainage of equipment can be prevented from being influenced by the too slow separation speed of the sewage and the sewage, in addition, the displacement seat can be driven to be attached to the outer surface of the filter screen layer through the operation of the electric control push rod, the second scraper can be attached to the inner surface of the filter screen layer through the fixing of the connecting seat, and when the shunt box drives the filter screen layer to rotate, the first scraper and the second scraper can always contact with the filter screen layer, and the dirt clamped in the filter screen layer can be separated from the filter screen layer through the auxiliary scraping of the first scraper and the second scraper, so that the dirt blocking the filter screen layer can be prevented from being influenced by the normal flow speed of the water.

4. After the separation of rain and sewage is completed by the diversion box, the sewage can enter the sewage drain pipe through the diversion box to be discharged, and the drain pipe is opened, so that the sewage can flow into the recovery box through the diversion box, alum is filled in the recovery box, the sewage can be kept still in the recovery box, the sewage can be purified in the recovery box, a valve at the outer end of the drain pipe is closed after the sewage is purified in the recovery box, the recovery box is drained, the recovery box is communicated with the sewage drain pipe through the second ventilation pipe, suction force generated when the recovery box drains water can be transmitted into the sewage drain pipe, suction force is generated in the sewage drain pipe, the sewage drain pipe can be promoted to flow so as not to influence normal use of the sewage drain pipe, in addition, the second crushing paddle is driven by the second motor to work, the sewage in the sewage drain pipe can be further crushed, the sewage is prevented from being excessively blocked in the sewage drain pipe, suction force is generated by the recovery box, and the common use of the second crushing paddle can greatly reduce the blockage rate of the sewage drain pipe.

Drawings

FIG. 1 is a schematic diagram of the overall structure of a rain and sewage shunt tube of the present invention in elevation, which can accelerate the flow rate and recycle the rain and sewage shunt tube;

FIG. 2 is a schematic diagram of a speed increasing assembly of a rain and sewage shunt tube capable of increasing the flow rate and recycling the rain and sewage shunt tube according to the invention;

FIG. 3 is an enlarged schematic view of the structure of the rain and sewage shunt of FIG. 1A, which is capable of accelerating the flow rate and recycling the rain and sewage shunt;

FIG. 4 is a schematic view of a driven gear and a driving gear of a rain and sewage shunt tube capable of accelerating the flow rate and recycling the rain and sewage shunt tube according to the present invention;

FIG. 5 is a schematic view of the structures of a first scraper and a second scraper of the rain and sewage shunt pipe capable of accelerating the flow rate and recycling the rain and sewage shunt pipe;

FIG. 6 is an enlarged schematic view of the structure of the rain and sewage shunt of FIG. 1 at B, which is capable of accelerating the flow rate and recycling the rain and sewage shunt according to the present invention;

fig. 7 is a schematic perspective view of a water diversion box with a rain and sewage diversion pipe capable of accelerating the flow rate and recycling the rain and sewage diversion pipe.

In the figure: 1. a water inlet pipe; 2. a shunt; 3. a speed increasing component; 301. a first water storage tank; 302. a second water storage tank; 303. a water-driven paddle; 304. a first turntable; 305. a drive belt; 306. a second turntable; 307. a first crushing paddle; 308. a first vent pipe; 4. collecting pipes; 5. a communicating pipe; 6. a water diversion box; 7. a first swivel mount; 8. a shunt box; 9. a filter screen layer; 10. a second swivel mount; 11. a blow-down pipe; 12. a driven gear; 13. a drive gear; 14. an electric control push rod; 15. a displacement seat; 16. a first scraper; 17. a connecting seat; 18. a second scraper; 19. a first motor; 20. a drain pipe; 21. a recovery box; 22. a second vent pipe; 23. a second motor; 24. and the second crushing paddle.

Detailed Description

Referring to fig. 1 to 7, the present invention provides the following technical solutions: the utility model provides a can accelerate velocity of flow and recycle's rain and sewage shunt tubes, including water inlet pipe 1, acceleration rate subassembly 3 and shunt box 8, the bottom outside of water inlet pipe 1 is connected with shunt tubes 2, acceleration rate subassembly 3 settles in the bottom outside of shunt tubes 2, and the bottom outside of acceleration rate subassembly 3 settles there is collecting main 4, the bottom outside of collecting main 4 settles communicating pipe 5, the outer end of communicating pipe 5 settles and have shunt box 6, and the bottom end of communicating pipe 5 is provided with first swivel base 7, shunt box 8 settles the bottom outside of first swivel base 7, the inboard middle-end of shunt box 8 is provided with filter screen layer 9, and the bottom outside of shunt box 8 settles and have second swivel base 10, the bottom outside of second swivel base 10 is connected with blow off pipe 11, the top outside of shunt box 8 is provided with driven gear 12, and the outer end of driven gear 12 settles and have driving gear 13, the inboard of shunt box 6 is provided with automatically controlled push rod 14, and the output of automatically controlled push rod 14 is connected with displacement seat 15, the outer end of displacement seat 15 settles and has first scraper blade 16, the inboard of 5 and blow off pipe 11 is provided with adaptor 17, and the motor of the outer end of second scraper blade 17 is settled to have the top of second swivel base 18, the top of second 19.

Referring to fig. 1 to 7, the speed increasing assembly 3 includes a first water storage tank 301, a second water storage tank 302, a water impeller 303, a first rotating disc 304, a driving belt 305, a second rotating disc 306, a first crushing impeller 307 and a first ventilation pipe 308, wherein the second water storage tank 302 is arranged on the outer side of the right portion of the first water storage tank 301, the water impeller 303 is arranged in the second water storage tank 302, the first rotating disc 304 is arranged at the outer end of the water impeller 303, the driving belt 305 is arranged on the outer side of the first rotating disc 304, the second rotating disc 306 is arranged on one side of the driving belt 305 far from the first rotating disc 304, the first crushing impeller 307 is connected to the output end of the second rotating disc 306, the first ventilation pipe 308 is arranged between the first water storage tank 301 and the second water storage tank 302, the driving belt 305 is driven to rotate by the first rotating disc 304, and the driving belt drives the first crushing impeller 307 to rotate by the second rotating disc 306, the first water storage tank 301 is communicated with the second water storage tank 302 through a first vent pipe 308, the size and the volume of the first water storage tank 301 and the second water storage tank 302 are consistent, the diversion tank 8 and the filter screen layer 9 are integrated, the diversion tank 8 rotates through a first rotating seat 7 and a second rotating seat 10, the first motor 19 drives the driving gear 13 to rotate, the driving gear 13 is meshed with the driven gear 12, the diversion tank 8 is fixedly connected with the driven gear 12, the first scraping plate 16 is jointed with the outer surface of the filter screen layer 9, the second scraping plate 18 is jointed with the inner surface of the filter screen layer 9, the joint seat 17 is fixedly connected with the communicating pipe 5 and the drain pipe 11, the joint seat 17 is fixedly connected with the second scraping plate 18, the outer end of the water diversion tank 6 is connected with the drain pipe 20, the tail end of the drain pipe 20 is connected with the recovery tank 21, the outer end of the recovery tank 21 is provided with a second vent pipe 22, the outer end of the drain pipe 11 is provided with a second motor 23, the output end of the second motor 23 is connected with a second crushing paddle 24, the recovery box 21 is communicated with the sewage drain pipe 11 through a second ventilation pipe 22, and the second crushing paddle 24 is arranged inside the sewage drain pipe 11;

the operation is as follows, when the city rains, municipal sewage can enter the inside of the device through the water inlet pipe 1, at this time, the valve at the left end of the shunt pipe 2 is closed, so that sewage can enter the inside of the second water storage tank 302 through the shunt pipe 2, at this time, the valve at the right end of the collecting pipe 4 is also in a closed state, so that sewage can be temporarily stored in the inside of the second water storage tank 302, when the sewage is stored in the second water storage tank 302, after the sewage is fully stored in the second water storage tank 302, the valve at the left end of the shunt pipe 2 is opened, the valve at the right end of the shunt pipe 2 is closed, so that sewage can flow to the inside of the first water storage tank 301, at this time, the valve at the right end of the collecting pipe 4 is converted into an opened state, and the valve at the left end of the collecting pipe 4 is converted into a closed state, so that the first water storage tank 301 can store sewage, and the second water storage tank 302 can discharge the stored sewage in the inside, therefore, the right end of the shunt pipe 2 is in a closed state, this allows the suction force of the second water storage tank 302 generated by the vacuum generated by the drainage to be transferred into the first water storage tank 301 through the first vent pipe 308, and at this time, the first water storage tank 301 is in a water storage state, by adding the vacuum suction force when the first water storage tank 301 stores water, the flow rate of the water flowing into the water pipe 1 can be raised, and by raising the flow rate of the water, the urban drainage pressure at the time of heavy rain can be greatly relieved, furthermore, after the first water storage tank 301 stores water, the shunt pipe 2 and the collector pipe 4 are switched again, which allows the suction force generated when the first water storage tank 301 drains water to be transferred into the second water storage tank 302, which allows the apparatus to continuously generate the suction force to raise the flow rate of the water, by which the apparatus can be made to raise the flow rate of the water in a simple manner of switching the water storage tanks, which allows the manner of raising the flow rate of the water of the apparatus to be simplified, because the equipment is usually buried underground, the fault rate of the equipment can be greatly reduced by arranging a simple water lifting flow mode, the use stability of the equipment is improved, the water flow can drive the water impeller 303 to rotate in the process of discharging water from the inside of the second water storage tank 302, the transmission belt 305 can be driven to rotate through the first rotating disc 304 in the process of rotating the water impeller 303, the second rotating disc 306 can drive the first crushing impeller 307 to rotate in the process of rotating the transmission belt 305, the first crushing impeller 307 is positioned at the inner side of the first water storage tank 301, the sundries which have larger inner volume and are clamped in the first water storage tank 301 can be crushed by rotating the first crushing impeller 307, the normal use of the first water storage tank 301 is prevented from being influenced by the sundries which are blocked by the first water storage tank 301, the sundries are crushed by the time of water inlet of the first crushing impeller 307, the method can avoid the influence of excessive water quantity on the normal use of the first crushing paddle 307, and simultaneously can ensure that the first crushing paddle 307 fully and uniformly stirs the sewage in water so as to facilitate the subsequent rain and sewage separation step, the rotation of the first crushing paddle 307 is realized by the drainage of the second water storage tank 302, so that the driving of the first crushing paddle 307 does not need to use an additional power source, the use and manufacturing cost of equipment can be reduced, the water impeller 303, the first rotating disc 304, the transmission belt 305, the second rotating disc 306 and the first crushing paddle 307 are symmetrically distributed in the first water storage tank 301 and the second water storage tank 302 at the other end of the first water storage tank 301, so that the first crushing paddle 307 can crush the sundries in the second water storage tank 302 when the first water storage tank 301 drains water, the sewage enters the inside of the distribution tank 8 through the communicating pipe 5, the driving gear 13 can drive the driven gear 12 to rotate through the first motor 19, because the split box 8 is connected with the driven gear 12, the split box 8 can rotate through the first rotating seat 7 and the second rotating seat 10, at the moment, because sewage and dirt are positioned in the split box 8, through the high-speed rotation of the split box 8, the sewage can flow into the inside of the split box 6 through the filter screen layer 9 under the action of centrifugal force, the dirt can be blocked and stored in the inside of the split box 6 by the filter screen layer 9, the separation speed of the sewage and the dirt can be improved through separating the sewage and the dirt through the centrifugal force, the normal drainage of the equipment can be prevented from being influenced by the too slow separation speed of the sewage and the dirt, in addition, the electric control push rod 14 works, the displacement seat 15 can drive the first scraping plate 16 to be attached to the outer surface of the filter screen layer 9, the second scraping plate 18 can be attached to the inner surface of the filter screen layer 9 through the fixing of the connecting seat 17, and when the split box 8 drives the filter screen layer 9 to rotate, the first scraping plate 16 and the second scraping plate 18 can be always contacted with the filter screen layer 9, the auxiliary scraping of the first scraping plate 16 and the second scraping plate 18 can separate dirt clamped in the filter screen layer 9 from the filter screen layer 9, so that the filter screen layer 9 can be prevented from being blocked by the dirt, the normal flow speed of water flow is influenced, the dirt can enter the sewage discharge pipe 11 to be discharged through the diversion box 8 after the diversion box 8 separates the rain and the dirt, the sewage can flow into the recovery box 21 through the diversion box 6 by opening the water discharge pipe 20, alum is filled in the recovery box 21, the sewage can stand in the recovery box 21, the sewage can be purified in the recovery box 21, the valve at the outer end of the water discharge pipe 20 is closed after the sewage is purified in the recovery box 21, the recovery box 21 is simultaneously discharged, the recovery box 21 is communicated with the sewage discharge pipe 11 through the second ventilation pipe 22, and the suction force generated when the recovery box 21 discharges water can be transmitted into the sewage discharge pipe 11, through making the interior suction that produces of blow off pipe 11, can promote the flow of the interior filth of blow off pipe 11 to avoid filth to block up in blow off pipe 11 and influence its normal use, in addition drive the work of second crushing oar 24 through second motor 23, can make the second crushing oar 24 further break to the filth in the blow off pipe 11, this can avoid the too big card of filth volume in blow off pipe 11 inside, produces suction through recovery tank 21 and the joint use of second crushing oar 24, can very big reduction blow off pipe 11's jam rate.

In summary, when the rain and sewage shunt tube capable of accelerating the flow rate and recycling is used, municipal sewage can enter the inner side of the device through the water inlet tube 1 when the city rains, at the moment, the valve at the left end of the shunt tube 2 is closed, so that the sewage can enter the second water storage tank 302 through the shunt tube 2, the valve at the right end of the collecting tube 4 is also in a closed state, the sewage can be temporarily stored in the second water storage tank 302, when the second water storage tank 302 is fully filled with the sewage, the valve at the left end of the shunt tube 2 is opened, the valve at the right end of the shunt tube 2 is closed, the sewage can be transferred into the first water storage tank 301, at the moment, the valve at the right end of the collecting tube 4 is converted into an open state, the valve at the left end of the collecting tube 4 is converted into a closed state, so that the first water storage tank 301 can store the sewage, the second water storage tank 302 can drain the stored sewage in the second water storage tank 302, so that the right end of the time division pipe 2 is in a closed state, the suction force formed by vacuum generated by the drainage of the second water storage tank 302 can be transmitted into the first water storage tank 301 through the first ventilation pipe 308, the first water storage tank 301 is in a water storage state, the flow rate of water flowing into the water pipe 1 can be improved by adding vacuum suction force when the first water storage tank 301 stores water, the urban drainage pressure during heavy rain can be greatly relieved by improving the flow rate of water, in addition, after the first water storage tank 301 is full of water, the division pipe 2 and the collecting pipe 4 are switched again, so that the suction force generated when the first water storage tank 301 drains water can be transmitted into the second water storage tank 302, and the equipment can continuously generate suction force to improve the flow rate of water;

then, in the process of discharging water flow from the inside of the second water storage tank 302, the water impeller 303 can be driven to rotate, in the process of rotating the water impeller 303, the first rotating disc 304 can drive the transmission belt 305 to rotate, in the process of rotating the transmission belt 305, the second rotating disc 306 can drive the first crushing impeller 307 to rotate, the first crushing impeller 307 is positioned at the inner side of the first water storage tank 301, and impurities which have larger inner volume and are blocked in the first water storage tank 301 can be crushed by rotating the first crushing impeller 307, so that the normal use of the first water storage tank 301 is prevented from being influenced by the impurities, and in addition, the normal use of the first crushing impeller 307 is prevented from being influenced by excessive water, and meanwhile, the sewage which is fed into the water can be fully and uniformly stirred by the first crushing impeller 307, so that the subsequent rainwater and sewage separation step is convenient;

then, after sewage and dirt enter the inside of the distribution box 8 through the communicating pipe 5, the first motor 19 works, the driving gear 13 can drive the driven gear 12 to rotate, the distribution box 8 can rotate through the first rotating seat 7 and the second rotating seat 10 due to the fact that the distribution box 8 is connected with the driven gear 12, at the moment, the sewage and dirt are positioned in the distribution box 8, the distribution box 8 rotates at a high speed, the sewage and dirt can flow into the inside of the distribution box 6 through the filter screen layer 9 under the action of centrifugal force, the dirt and dirt can be blocked and stored in the inside of the distribution box 6 by the filter screen layer 9, the separation speed of the sewage and dirt can be improved through the centrifugal force, the normal drainage of equipment can be prevented from being influenced by the too slow separation speed of the sewage and dirt, in addition, the operation of the electric control push rod 14 can enable the displacement seat 15 to drive the first scraper 16 to be attached to the outer surface of the filter screen layer 9, the second scraper 18 can be attached to the inner surface of the filter screen layer 9 through the fixing of the connecting seat 17, the first scraper 16 and the second scraper 18 can always contact the filter screen layer 9 when the distribution box 8 drives the filter screen layer 9 to rotate, the first scraper 16 and the second scraper 18 can be blocked and the filter screen layer 9, and the dirt can be prevented from being blocked and blocked by the filter screen layer 9, and the normal dirt can be prevented from being separated from the normal flow;

finally, after the separation of rain and sewage is completed by the diversion box 8, sewage can enter the sewage drain pipe 11 through the diversion box 8 to be discharged, and the drain pipe 20 is opened, so that sewage can flow into the recovery box 21 through the diversion box 6, alum is filled in the recovery box 21, and the sewage can stand in the recovery box 21, so that the sewage can be purified in the recovery box 21, after the purification of the sewage in the recovery box 21 is completed, the valve at the outer end of the drain pipe 20 is closed, the recovery box 21 is simultaneously used for draining water, the recovery box 21 is communicated with the sewage drain pipe 11 through the second vent pipe 22, suction force generated during the drainage of the recovery box 21 can be transmitted into the sewage drain pipe 11, the flow of the sewage in the sewage drain pipe 11 can be promoted through the suction force generated in the sewage drain pipe 11, so that the sewage is prevented from being blocked in the sewage drain pipe 11 to influence normal use, in addition, the second motor 23 drives the second crushing paddle 24 to work, the sewage in the sewage drain pipe 11 can be prevented from being further crushed, the sewage volume is excessively blocked in the sewage drain pipe 11, the sewage drain pipe 21 is simultaneously drained, the suction force generated through the recovery box 21, and the sewage drain pipe is greatly crushed by the second crushing paddle 24, and the sewage drain pipe 11 is greatly used together.

The embodiments of the invention have been presented for purposes of illustration and description, and are not intended to be exhaustive or limited to the invention in the form disclosed. Many modifications and variations will be apparent to those of ordinary skill in the art. The embodiments were chosen and described in order to best explain the principles of the invention and the practical application, and to enable others of ordinary skill in the art to understand the invention for various embodiments with various modifications as are suited to the particular use contemplated.

Claims (9)

1. Can accelerate the rain sewage shunt tubes of velocity of flow and recycle, a serial communication port, including income water pipe (1), acceleration rate subassembly (3) and shunt box (8), the bottom outside of income water pipe (1) is connected with shunt tube (2), acceleration rate subassembly (3) are settled in the bottom outside of shunt tube (2), and settle in the bottom outside of acceleration rate subassembly (3) has collecting pipe (4), settle in the bottom outside of collecting pipe (4) has communicating pipe (5), settle in the outer end of communicating pipe (5) has shunt box (6), and the bottom end of communicating pipe (5) is provided with first seat of rotation (7), shunt box (8) are settled in the bottom outside of first seat of rotation (7), the inboard middle-end of shunt box (8) is provided with filter screen layer (9), and settle in the bottom outside of shunt box (8) has second swivel mount (10), the bottom outside of second swivel mount (10) is connected with blow off pipe (11), the top outside of shunt box (8) is provided with driven gear (12), and driven gear (12) outer end of outer end, and end of driving gear (6) is settled in the outer end of a push rod (14), and the displacement of the push rod (14) is settled in the outer end of the first seat of rotation (14), the inner sides of the communicating pipe (5) and the sewage draining pipe (11) are provided with a connecting seat (17), the outer end of the connecting seat (17) is provided with a second scraping plate (18), and the top of the right side of the water distribution box (6) is provided with a first motor (19);

the speed increasing assembly (3) comprises a first water storage tank (301), a second water storage tank (302), a water moving paddle (303), a first rotating disc (304), a driving belt (305), a second rotating disc (306), a first crushing paddle (307) and a first ventilation pipe (308), wherein the second water storage tank (302) is arranged on the outer side of the right part of the first water storage tank (301), the water moving paddle (303) is arranged in the second water storage tank (302), the first rotating disc (304) is arranged at the outer end of the water moving paddle (303), the driving belt (305) is arranged on the outer side of the first rotating disc (304), the second rotating disc (306) is arranged on one side, far away from the first rotating disc (304), of the driving belt (305), the output end of the second rotating disc (306) is connected with the first crushing paddle (307), and the first ventilation pipe (308) is arranged between the first water storage tank (301) and the second water storage tank (302).

2. A rain and sewage shunt tube capable of accelerating flow rate and recycling according to claim 1, characterized in that the water impeller (303) drives the transmission belt (305) to rotate through the first rotating disc (304), and the transmission belt (305) drives the first crushing impeller (307) to rotate through the second rotating disc (306).

3. The rain and sewage shunt pipe capable of accelerating flow rate and recycling according to claim 1, wherein the first water storage tank (301) is communicated with the second water storage tank (302) through a first vent pipe (308), and the size and the volume of the first water storage tank (301) are consistent with those of the second water storage tank (302).

4. A rain and sewage shunt tube capable of accelerating flow rate and recycling according to claim 1, characterized in that the shunt box (8) is integrated with the filter screen layer (9), and the shunt box (8) rotates through the first rotating seat (7) and the second rotating seat (10).

5. A rain and sewage shunt tube capable of accelerating flow rate and recycling according to claim 1, characterized in that the first motor (19) drives the driving gear (13) to rotate, the driving gear (13) is meshed with the driven gear (12), and the shunt box (8) is fixedly connected with the driven gear (12).

6. A flow rate quickening and recycling rain and sewage shunt tube according to claim 1, characterized in that the first scraping plate (16) is jointed with the outer surface of the filter screen layer (9), and the second scraping plate (18) is jointed with the inner surface of the filter screen layer (9).

7. The rain and sewage shunt tube capable of accelerating flow rate and recycling according to claim 1, wherein the connecting seat (17) is fixedly connected with the communicating tube (5) and the sewage draining tube (11), and the connecting seat (17) is fixedly connected with the second scraping plate (18).

8. The rain and sewage shunt tube capable of accelerating flow rate and recycling according to claim 1, wherein the outer end of the water diversion box (6) is connected with a drain pipe (20), the tail end of the drain pipe (20) is connected with a recovery box (21), the outer end of the recovery box (21) is provided with a second vent pipe (22), the outer end of the sewage drain tube (11) is provided with a second motor (23), and the output end of the second motor (23) is connected with a second crushing paddle (24).

9. A flow-rate-accelerating and recycling rain and sewage shunt pipe according to claim 8, characterized in that said recycling bin (21) is connected to the sewage drain pipe (11) by means of a second vent pipe (22), and that a second crushing paddle (24) is arranged inside the sewage drain pipe (11).