CN110607828A

CN110607828A - Automatic desilting pipeline of blowdown

Info

Publication number: CN110607828A
Application number: CN201911026257.3A
Authority: CN
Inventors: 左雪云
Original assignee: Individual
Current assignee: Jiangxi Jinshifei Construction Engineering Co ltd
Priority date: 2019-10-25
Filing date: 2019-10-25
Publication date: 2019-12-24
Anticipated expiration: 2039-10-25
Also published as: CN110607828B

Abstract

The invention discloses a sewage discharge automatic dredging pipeline, which comprises a pipeline body, wherein a pipeline inner cavity is arranged in the pipeline body, the bottom of the pipeline body is connected with a settling pipe in parallel, the settling pipe is connected with a discharge pipe parallel to the pipeline body, a sedimentation inner cavity is respectively arranged in the sedimentation pipes, one end of each sedimentation pipe is provided with a first rotating shaft which rotates, the first rotating shafts are respectively provided with a first blocking plate which rotates in the sedimentation inner cavity, the other ends of the sedimentation pipes are respectively provided with a second rotating shaft which rotates, the second rotating shafts are respectively provided with a second plugging plate which rotates in the sedimentation inner cavity and can seal the sedimentation inner cavity through the first plugging plate and the second plugging plate, thereby further collecting the sludge and avoiding the blockage of the pipeline caused by the sludge.

Description

Automatic desilting pipeline of blowdown

Technical Field

The invention relates to a sewage discharge pipeline, in particular to an automatic sewage discharge dredging pipeline, and particularly relates to an automatic sewage discharge dredging pipeline capable of realizing automatic sedimentation and discharge of sludge in a pipeline.

Background

Along with the continuous improvement of urban construction, the urban infrastructure is further promoted, wherein the sewage discharge pipe is one of essential infrastructures in the current urban construction process, so that urban sewage can be further guided and discharged through the sewage discharge pipe, the pipeline laying is mostly completed through the connection of a pipe body structure in the process of laying the sewage discharge pipe, although the aim of sewage discharge can be achieved through the sewage discharge pipe, in the process of sewage discharge by utilizing the pipeline, because the sewage is mixed with a large amount of soil in circulation, when the sewage mixed with the soil sinks to the bottom of the sewage discharge pipe in the circulation process, the soil deposited to the bottom of the sewage discharge pipe can be hardened along with the accumulation of time, thereby causing serious influence on the sewage discharge, because the space of the sewage discharge pipe is narrow and small, the sewage discharge pipe cannot be cleaned in time, thereby further influencing the normal discharge function of the sewage draining pipe.

Therefore, there is a need to design an automatic dredging pipeline for sewage disposal to solve the above technical problems.

Disclosure of Invention

The present invention is directed to overcome the problems of the prior art, and provides an automatic dredging pipe for sewage drainage, which can be provided with a settling pipe at the bottom of a pipe body, so that sludge mixed with sewage can be further automatically settled in the settling pipe during the process of discharging sewage through the pipe body, thereby completing the automatic settling of sludge, and simultaneously, the sludge can be further automatically circulated and discharged into the pipe through the sealing of the settling inner chamber by the first blocking plate and the second blocking plate, thereby further transporting and discharging sludge through the pipe, thereby preventing the sludge from settling in the pipe inner chamber and blocking the pipe inner chamber.

The invention is realized by the following technical scheme:

an automatic dredging pipeline for sewage disposal, comprising a pipeline body, wherein a pipeline inner cavity is arranged in the pipeline body, the bottom of the pipeline body is connected with a settling tube side by side, the settling tube is connected with a row of pipes which are parallel to the pipeline body, a settling inner cavity is respectively arranged in the settling tube, the settling inner cavity is respectively correspondingly communicated with the pipeline inner cavity, one end of the settling tube is provided with a rotating first rotating shaft, the first rotating shaft is respectively provided with a first blocking plate which rotates in the settling inner cavity, the other end of the settling tube is respectively provided with a rotating second rotating shaft, the second rotating shaft is respectively provided with a second blocking plate which rotates in the settling inner cavity, the first blocking plate and the second blocking plate are correspondingly arranged, and the first blocking plate and the second blocking plate respectively seal the settling inner cavity, one end of the settling tube is provided with a first control module respectively, the other end of the settling tube is provided with a second control module respectively, a fifth rotating shaft for rotation is arranged on the second control module respectively, and the fifth rotating shaft controls the first rotating shaft and the second rotating shaft to rotate synchronously. The sewage can further cause the sludge in the sewage to automatically deposit in the sedimentation inner cavity in the circulating process, and the sedimentation inner cavity is controlled through the first blocking plate and the second blocking plate, so that the sludge can automatically circulate in the pipe, the sludge can be automatically discharged through the pipe, the sludge can be further prevented from blocking the inner cavity of the pipe, and the normal function of the inner cavity of the pipe body is ensured.

Furthermore, a first bevel gear is respectively arranged on the first rotating shaft, a fourth bevel gear is respectively arranged on the second rotating shaft, a third rotating shaft is respectively arranged between the first control module and the second control module, one end of the third rotating shaft is respectively provided with a second bevel gear correspondingly engaged and connected with the first bevel gear, the other end of the third rotating shaft is respectively provided with a third bevel gear correspondingly engaged and connected with the fourth bevel gear, a rotating fourth rotating shaft is respectively arranged in the second control modules, a fifth bevel gear correspondingly meshed and connected with the third bevel gear is respectively arranged at one end of the fourth rotating shaft, and the other end of the fourth rotating shaft is respectively provided with a sixth bevel gear, and the fifth rotating shaft is respectively provided with a seventh bevel gear correspondingly meshed and connected with the sixth bevel gear.

Furthermore, a second sliding shaft which slides is respectively arranged between the first control module and the second control module, the first control module and the second control module are respectively provided with a supporting slide hole for supporting the second slide shaft to slide, the first rotating shaft is respectively provided with a second gear, the second sliding shafts are respectively provided with a section of second tooth groove correspondingly engaged and connected with the second gear, the second rotating shafts are respectively provided with a first gear, the second sliding shafts are respectively provided with a section of first tooth groove correspondingly engaged and connected with the first gear, and the fifth rotating shaft is respectively provided with a third gear, the second sliding shaft is respectively provided with a section of third tooth groove correspondingly meshed and connected with the third gear, and the second sliding shaft and the supporting sliding hole are respectively arranged in a square shape.

Furthermore, the pipeline body is connected with first connecting pipes respectively, the row pipes are connected with second connecting pipes corresponding to the first connecting pipes respectively, the settling pipe is clamped between the first connecting pipes and the second connecting pipes, and two ends of the settling pipe are connected to the first connecting pipes and the second connecting pipes respectively through a threaded connecting sleeve.

Furthermore, two adjacent fifth rotating shafts are correspondingly connected through a connecting rotating shaft respectively, two ends of each connecting rotating shaft are provided with a first sliding hole respectively, a first sliding shaft is arranged in each first sliding hole, a first spring which is used for pressing the first sliding shaft is arranged in each first sliding hole, the end part of each fifth rotating shaft is provided with a linking sliding hole respectively, each connecting sliding hole, each first sliding shaft and each first sliding hole are arranged in a square shape respectively, each connecting rotating shaft is provided with a supporting sliding groove which is communicated with the corresponding first sliding hole, each first sliding shaft is provided with a pulling shaft which slides in the supporting sliding groove, and the second control module is provided with a servo motor which drives the fifth rotating shafts to rotate.

Furthermore, the outer edges of the first blocking plate and the second blocking plate are respectively provided with a sealing gasket.

Further, the settling tube is arranged at the bottom of the pipeline body.

Furthermore, in the process of circulating the sewage in the inner cavity of the pipeline, a large amount of impurities are mixed in the sewage, and when the impurities in the sewage are further precipitated to the bottom of the inner cavity of the pipeline, the sludge can be precipitated at the bottom of the inner cavity of the pipeline;

the bottom of the pipeline body is provided with the sedimentation pipes side by side, and the sedimentation pipes are respectively provided with a sedimentation inner cavity, so that sludge in the sewage can be automatically precipitated into the sedimentation inner cavities in the circulation process of the sewage, and the sludge can be further prevented from being precipitated to the bottom of the pipeline inner cavity;

the pipe body is laid and arranged on the settling pipe while the pipe body is laid, and the pipe is connected to the settling pipe, so that the sludge in the settling cavity can be circulated to the pipe, and the sludge can be automatically discharged through the pipe, thereby avoiding the problem of pipe blockage caused by the sludge settling to the bottom of the pipe cavity and avoiding the trouble caused by manual cleaning;

a first blocking plate and a second blocking plate are respectively arranged at two ends of the tube, the first blocking plate and the second blocking plate can control the opening and closing of the sedimentation cavity, when the first blocking plate is opened, the second blocking plate seals the bottom of the sedimentation cavity, so that sludge is sedimentated in the sedimentation cavity, when the first blocking plate is closed, the second blocking plate is opened, so that sludge can be automatically circulated and discharged in the tube, and sludge can be further discharged through the tube.

Compared with the prior art, the invention has the beneficial effects that: can set up the sedimentation pipe in the bottom of the pipeline body, in the in-process that flows through at the pipeline inner chamber when sewage can make the automatic sediment of silt that mix with in the sewage in the sedimentation pipe, be provided with pivoted first closure plate and second closure plate in the sedimentation intracavity, thereby can deposit the closure and the opening of inner chamber through first closure plate and second closure plate control, thereby can further control the sediment and the emission of silt, thereby can make the silt circulate and arrange in intraductally, thereby can further discharge silt through arranging in the pipe, thereby avoided silt to deposit in the pipeline cause stifled, thereby guarantee the normal discharge function of pipeline, the trouble that the manual work can't clear up the cause has been avoided simultaneously.

Drawings

The invention is further described below with reference to the accompanying drawings.

FIG. 1 is a schematic view of the overall structure of an automatic dredging pipeline for sewage discharge according to an embodiment of the present invention.

FIG. 2 is a side view of the whole structure of the automatic dredging pipe for sewage discharge in the embodiment of the invention.

Fig. 3 is a schematic diagram of a first structure of the first control module and the second control module according to the present invention.

Fig. 4 is a schematic diagram of a first structure of a second module according to an embodiment of the present invention.

Fig. 5 is a schematic view of a fifth rotating shaft connection structure according to an embodiment of the invention.

Fig. 6 is a schematic diagram of a second structure of the first control module and the second control module according to the embodiment of the present invention.

Fig. 7 is a second structural diagram of a second control module according to the embodiment of the invention.

Fig. 8 is a schematic view of the overall structure of the connecting shaft according to the embodiment of the present invention.

In the figure: 1 pipeline body, 2 pipeline inner cavity, 3 settling pipe, 4 settling inner cavity, 5 row pipes, 6 first blocking plate, 7 second blocking plate, 8 first connecting pipe, 9 second connecting pipe, 10 threaded connecting sleeve, 11 first rotating shaft, 12 second rotating shaft, 13 first control module, 14 second control module, 15 third rotating shaft, 16 first bevel gear, 17 second bevel gear, 18 third bevel gear, 19 fourth bevel gear, 20 fifth bevel gear, 21 fourth rotating shaft, 22 sixth bevel gear, 23 seventh bevel gear, 24 fifth rotating shaft, 25 connecting rotating shaft, 26 servo motor, 27 first sliding hole, 28 first sliding shaft, 29 first spring, 30 connecting sliding hole, 31 second sliding shaft, 32 supporting sliding hole, 33 first gear, 34 first tooth groove, 35 second gear, 36 second tooth groove, 37 third gear, 38 third tooth groove, 39 pulling shaft, 40 supporting sliding groove.

Detailed Description

As shown in fig. 1 to 8, an automatic dredging pipe for sewage disposal comprises a pipe body 1, a pipe cavity 2 is disposed in the pipe body 1, settling tubes 3 are connected to the bottom of the pipe body 1 side by side, the settling tubes 3 are connected to a row of pipes 5 parallel to the pipe body 1, a settling cavity 4 is disposed in each settling tube 3, the settling cavities 4 are respectively communicated with the pipe cavity 2, a first rotating shaft 11 is disposed at one end of each settling tube 3, a first blocking plate 6 rotating in the settling cavity 4 is disposed on each first rotating shaft 11, a second rotating shaft 12 rotating is disposed at the other end of each settling tube 3, a second blocking plate 7 rotating in the settling cavity 4 is disposed on each second rotating shaft 12, and the first blocking plate 6 and the second blocking plate 7 are disposed correspondingly, first closure plate 6 with second closure plate 7 is sealed respectively deposit inner chamber 4, the one end of sedimentation pipe 3 is provided with a first control module 13 respectively, the other end of sedimentation pipe 3 is provided with a second control module 14 respectively, be provided with a pivoted fifth pivot 24 on the second control module 14 respectively, fifth pivot 24 control first pivot 11 and second pivot 12 synchronous rotation.

The pipeline body 1 is a cylindrical pipeline, a pipeline inner cavity 2 is arranged in the pipeline body, the pipeline body 1 is correspondingly connected in parallel in the process of laying the pipeline body 1, so that sewage can be discharged through the pipeline inner cavity 2, settling tubes 3 are respectively arranged at the bottom of the pipeline body 1, the number of the settling tubes 3 is set according to the design requirement, a laying and discharging pipe 5 is required to be laid when the pipeline body 1 is laid, the number of the laying and discharging pipe 5 is set according to the length of the pipeline body 1, the settling tubes 3 are respectively connected on the laying and discharging pipe 5, a settling inner cavity 4 is respectively arranged in the settling tube 3, the settling inner cavity 4 is in a hollow groove shape, the settling tube 3 is arranged in a cylindrical shape, a first rotating shaft 11 is respectively arranged at one end of the settling tube 3, a second rotating shaft 12 is respectively arranged at the other end of the settling tube 3, a first blocking plate 6 is respectively arranged on a first rotating shaft 11, a second blocking plate 7 is respectively arranged on a second rotating shaft 12, the first blocking plate 6 and the second blocking plate 7 can be driven to rotate by the rotation of the first rotating shaft 11 and the rotation of the second rotating shaft 12, the diameters of the first blocking plate 6 and the second blocking plate 7 are the same, the first blocking plate 6 and the second blocking plate 7 are vertically arranged, the first blocking plate 6 and the second blocking plate 7 can seal the sedimentation inner cavity 4 in the rotating process, the second blocking plate 7 is in an open state when the first blocking plate 6 seals the sedimentation inner cavity 4, the second blocking plate 7 seals the sedimentation inner cavity 4 when the first blocking plate 6 is in the open state, a first control module 13 is respectively arranged at one end of the sedimentation pipe 3, and a second control module 14 is respectively arranged at the other end of the sedimentation pipe 3, a fifth rotating shaft 24 is respectively arranged on the second control module 14, and the fifth rotating shaft 24 can drive the first rotating shaft 11 and the second rotating shaft 12 to synchronously rotate;

when the sewage is discharged by using the inner cavity 2 of the pipeline, a large amount of sludge is mixed in the sewage, and most of the sludge is precipitated at the bottom of the inner cavity 2 of the pipeline in the circulating process of the sludge, and when the first blocking plate 6 is in an open state to the inner cavity 4 of the pipeline, the second blocking plate 7 is in a sealed state to the inner cavity 4 of the pipeline, so that a large amount of soil is precipitated in the inner cavity 4 of the pipeline, thereby avoiding the problem caused by the precipitation of the sludge at the bottom of the inner cavity 2 of the pipeline, the first rotating shaft 11 and the second rotating shaft 12 can be driven to synchronously rotate by the rotation of the fifth rotating shaft 24, so that the first blocking plate 6 is in a sealed state to the inner cavity 4 of the pipeline, and the second blocking plate 7 is in an open state to the inner cavity 4 of the pipeline, thereby further circulating the sludge to be discharged into the pipe 5, thereby further dispatching and treating the sludge by discharging the pipe 5, thereby avoided silt to deposit the jam that causes the pipeline body 1 in the pipeline inner chamber 4 to guarantee the normal discharge function of pipeline, avoided the trouble that artifical unable clearance caused simultaneously.

As shown in fig. 1 to 5, a first bevel gear 16 is respectively disposed on the first rotating shafts 11, a fourth bevel gear 19 is respectively disposed on the second rotating shafts 12, a third rotating shaft 15 rotating is respectively disposed between the first control module 13 and the second control module 14, one end of the third rotating shaft 15 is respectively provided with a second bevel gear 17 correspondingly engaged with the first bevel gear 16, the other end of the third rotating shaft 15 is respectively provided with a third bevel gear 18 correspondingly engaged with the fourth bevel gear 19, a fourth rotating shaft 21 rotating is respectively disposed in the second control module 14, one end of the fourth rotating shaft 21 is respectively provided with a fifth bevel gear 20 correspondingly engaged with the third bevel gear 18, the other end of the fourth rotating shaft 21 is respectively provided with a sixth bevel gear 22, and the fifth rotating shafts 24 are respectively provided with a seventh bevel gear 23 which is correspondingly meshed and connected with the sixth bevel gear 22.

(as shown in fig. 1 to 5 are schematic diagrams of a first structure of the present invention), a first bevel gear 16 is respectively disposed on the first rotating shaft 11, a fourth bevel gear 19 is respectively disposed on the second rotating shaft 12, the first control module 13 and the second control module 14 are respectively connected to the pipeline body 1, a rotating third rotating shaft 15 is respectively disposed between the first control module 13 and the second control module 14, a first bevel gear 16 is respectively disposed at one end of the third rotating shaft 15, the first bevel gear 16 and the second bevel gear 17 are correspondingly engaged and connected, a third bevel gear 18 is respectively disposed at the other end of the third rotating shaft 15, the third bevel gear 18 and the fourth bevel gear 19 are correspondingly engaged and connected, a rotating fourth rotating shaft 21 is respectively disposed in the second control module 14, a fifth bevel gear 20 is respectively disposed at one end of the fourth rotating shaft 21, the fifth bevel gears 20 are respectively correspondingly engaged with the third bevel gears 18, the other ends of the fourth rotating shafts 21 are respectively provided with a sixth bevel gear 22, the fifth rotating shafts 24 are respectively provided with a seventh bevel gear 23, the seventh bevel gears 23 are correspondingly engaged with the sixth bevel gears 22, so that the fourth rotating shafts 21 can be further driven to rotate by the rotation of the fifth bevel gears 24, the third rotating shafts 15 can be driven to rotate by the rotation of the fourth rotating shafts 21, the first rotating shafts 11 and the second rotating shafts 12 can be simultaneously driven to synchronously rotate by the rotation of the third rotating shafts 15, the first blocking plates 6 and the second blocking plates 7 can be further driven to synchronously rotate, the communication and the closing of the precipitation inner chambers 4 can be controlled, and when the first blocking plates 6 are in a closed state relative to the precipitation inner chambers 4, the second blocking plates 7 are in an open state relative to the precipitation inner chambers 4, therefore, the sludge can further flow into the pipe 5 through the sedimentation inner cavity 4, and when the first blocking plate 6 is in the open state, the second blocking plate 7 is in the closed state, so that the sludge in the inner cavity 2 of the pipeline can further flow into the sedimentation inner cavity 4, and the sludge can further be precipitated into the sedimentation inner cavity 4, thereby avoiding the sludge from precipitating into the inner cavity 2 of the pipeline to block the inner cavity 2 of the pipeline.

As shown in fig. 1, 6 and 7, a sliding second sliding shaft 31 is respectively disposed between the first control module 13 and the second control module 14, a supporting sliding hole 32 for supporting the sliding second sliding shaft 31 is respectively disposed on the first control module 13 and the second control module 14, a second gear 35 is respectively disposed on the first rotating shaft 11, a second tooth groove 36 correspondingly engaged with the second gear 35 is respectively disposed on the second sliding shaft 31, a first gear 33 is respectively disposed on the second rotating shaft 12, a first tooth groove 34 correspondingly engaged with the first gear 33 is respectively disposed on the second sliding shaft 31, a third gear 37 is respectively disposed on the fifth rotating shaft 24, a third tooth groove 38 correspondingly engaged with the third gear 37 is respectively disposed on the second sliding shaft 31, the second sliding shaft 31 and the supporting sliding hole 32 are respectively arranged in a square shape.

(for example, fig. 1, 6 and 7 are schematic structural diagrams of a second embodiment of the present invention), a second sliding shaft 31 is disposed between the first control module 13 and the second control module 14, the second sliding shaft 31 can slide between the first control module 13 and the second control module 14, and can support the second sliding shaft 31 through the supporting sliding hole 32, so as to ensure the normal sliding of the second sliding shaft 31, a second gear 35 is disposed on the first rotating shaft 11, a section of second tooth groove 36 is disposed at one end of the second sliding shaft 31, the second tooth groove 36 is correspondingly engaged with the second gear 35, a first gear 33 is disposed on the second rotating shaft, a first tooth groove 34 is disposed at the other end of the second sliding shaft 31, the first tooth groove 34 is correspondingly engaged with the first gear 33, so that the first gear 33 and the second tooth groove 35 can be simultaneously driven to rotate by the up-down sliding of the second sliding shaft 31, thereby can further drive the synchronous rotation of first pivot 11 and second pivot 12, the rotation of the first closure plate 6 of further control and second closure plate 7, be provided with a third gear 37 on fifth pivot 24 respectively, be provided with one section third tooth's socket 38 on second sliding shaft 31 respectively, third gear 37 is connected with the corresponding meshing of third tooth's socket 38, thereby can further drive the rotation of third gear 37 through the rotation of fifth pivot 24, thereby can further drive the up-and-down slip of second sliding shaft 31, thereby the rotation of control first closure plate 6 and second closure plate 7, second sliding shaft 31 and support slide opening 32 are square setting respectively.

As shown in fig. 2, the first connecting pipes 8 are respectively connected to the pipe body 1, the second connecting pipes 9 corresponding to the first connecting pipes 8 are respectively connected to the row pipes 5, after the settling pipe 3 is clamped between the first connecting pipes 8 and the second connecting pipes 9, two ends of the settling pipe 3 are respectively connected to the first connecting pipes 8 and the second connecting pipes 9 through a threaded connecting sleeve 10.

The pipeline body 1 is respectively provided with a first connecting pipe 8, the number of the first connecting pipes 8 is set according to the design requirement, the second connecting pipes 9 are installed on the row pipes 5, the number of the second connecting pipes 9 is installed according to the design requirement, the position of the second connecting pipe 9 is corresponding to the position of the first connecting pipe 8, the settling tube 3 can be installed between the first connection tube 8 and the second connection tube 9 during the installation of the settling tube 3, the two ends of the settling tube 3 are respectively connected with the first connecting tube 8 and the second connecting tube 9 through the threaded connecting sleeve 10, the first connecting tube 8 and the second connecting tube 9 as well as the two ends of the settling tube 3 are respectively provided with threads, so that the settling tube 3 can be connected to the first connecting tube 8 and the second connecting tube 9 through the screw coupling sleeve 10, thereby further facilitating the installation and removal of the settling tube 3.

As shown in fig. 5 and 8, two adjacent fifth rotating shafts 24 are correspondingly connected through a connecting rotating shaft 25, two ends of the connecting rotating shaft 25 are respectively provided with a first sliding hole 27, a first sliding shaft 28 is respectively arranged in the first sliding holes 27, a first spring 29 for biasing the first slide shaft 28 is disposed in each of the first slide holes 27, the end of the fifth rotating shaft 14 is respectively provided with a linking sliding hole 30, the first sliding shaft 28 and the first sliding hole 27 are respectively arranged in a square shape, the connecting rotating shafts 25 are respectively provided with a supporting sliding chute 40 correspondingly communicated with the first sliding hole 27, the first slide shafts 28 are respectively provided with a pulling shaft 39 that slides in the support slide grooves 40, the second control module 14 is provided with a servo motor 26 for driving the fifth rotating shaft 24 to rotate.

The settling tubes 3 are arranged side by side, the fifth rotating shafts 24 arranged between two adjacent settling tubes 3 are correspondingly connected through a connecting rotating shaft 25 respectively, the number of the connecting rotating shafts 25 can be set according to the design requirement, so that the fifth rotating shafts 24 can be connected in series through the connecting rotating shafts 25, the fifth rotating shafts 24 can further synchronously rotate, the sludge discharge of the settling tubes 3 can be further controlled, in the process of installing the connecting rotating shafts 25, the first sliding shafts 28 can be further pulled to slide through the pulling shafts 39, the connecting sliding holes 30 are respectively arranged at two ends of the fifth rotating shafts 24, so that the first sliding shafts 28 can further slide in the connecting sliding holes 30, the first sliding shafts 28 can be controlled to be separated from the connecting sliding shafts 30 to slide, and the first sliding shafts 28 can be elastically pressed through the first springs 29, the first sliding shaft 28 can be further pressed in the connecting sliding hole 30, the first sliding shaft 28 and the connecting sliding hole 30 are respectively arranged in a square shape, so that the rotation of the fifth rotating shaft 24 can be further controlled through the rotation of the connecting rotating shaft 25, the fifth rotating shafts 24 arranged side by side can be connected in series, the number of the series-connected fifth rotating shafts 24 is set according to the design requirement, the servo motor 26 is arranged on the second control module 14, the rotation of the fifth rotating shaft 24 can be further driven through the private clothes motor 26, the rotation of the fifth rotating shaft 24 can be further controlled, and meanwhile, the wireless control module can be arranged on the second control module 14, the rotation of the private clothes motor 26 can be further controlled, and the arrangement of the sedimentation pipes 3 can be controlled.

As shown in fig. 2, the first blocking plate 6 and the second blocking plate 7 are respectively provided with a sealing gasket at the outer edge. The sealing of the first closure plate 6 and the second closure plate 7 against the precipitation interior 4 can be further ensured by means of sealing gaskets.

As shown in fig. 1 and 2, the settling tube 3 is disposed at the bottom of the pipe body 1. The settling tube 3 can be disposed at the bottom of the pipe body 1, so that the sludge can be further automatically settled in the settling tube 3.

The working principle of the invention is as follows: in the process that the sewage flows in the inner cavity 2 of the pipeline, a large amount of impurities are mixed in the sewage, and when the impurities in the sewage are further precipitated at the bottom of the inner cavity 2 of the pipeline, the sludge can be precipitated at the bottom of the inner cavity 2 of the pipeline;

the bottom of the pipeline body 1 is provided with the sedimentation pipes 3 side by side, and the sedimentation pipes 3 are respectively provided with the sedimentation inner cavities 4, so that sludge in the sewage can be automatically precipitated in the sedimentation inner cavities 4 in the circulation process of the sewage, and the sludge can be further prevented from being precipitated at the bottom of the pipeline inner cavity 2;

the pipe 5 is laid while the pipe body 1 is laid, and the pipe 5 is connected to the settling pipe 3, so that the sludge in the settling chamber 4 can be circulated into the pipe 5, and the sludge can be automatically discharged through the pipe 5, thereby preventing the problem of pipe blockage caused by the sludge settling to the bottom of the pipe chamber 2 and avoiding the trouble caused by manual cleaning;

a first blocking plate 6 and a second blocking plate 7 are respectively arranged at two ends of the tube 5 for rotation, the first blocking plate 6 and the second blocking plate 7 can control the opening and closing of the sedimentation chamber 4, when the first blocking plate 6 is opened, the second blocking plate 7 seals the bottom of the sedimentation chamber 4, so that the sludge is sedimented in the sedimentation chamber 4, when the first blocking plate 6 is closed, the second blocking plate 7 is opened, so that the sludge can be automatically circulated to the tube 5, and the sludge can be further discharged through the tube 5.

Claims

1. The utility model provides an automatic desilting pipeline of blowdown, including a pipeline body, be provided with pipeline inner chamber in the pipeline body, its characterized in that: the bottom of the pipeline body is connected with precipitation pipes side by side, the precipitation pipes are connected with a pipe which is parallel to the pipeline body, a precipitation inner cavity is respectively arranged in the precipitation pipes, the precipitation inner cavity is respectively correspondingly communicated with the pipeline inner cavity, one end of each precipitation pipe is provided with a first rotating shaft, the first rotating shaft is respectively provided with a first blocking plate which rotates in the precipitation inner cavity, the other end of each precipitation pipe is respectively provided with a second rotating shaft which rotates, the second rotating shaft is respectively provided with a second blocking plate which rotates in the precipitation inner cavity, the first blocking plate and the second blocking plate are correspondingly arranged, the first blocking plate and the second blocking plate respectively seal the precipitation inner cavity, one end of each precipitation pipe is respectively provided with a first control module, and the other end of each precipitation pipe is respectively provided with a second control module, and the second control module is respectively provided with a fifth rotating shaft for rotating, and the fifth rotating shaft controls the first rotating shaft and the second rotating shaft to rotate synchronously.

2. The automatic dredging pipeline for sewage discharge according to claim 1, characterized in that: the first rotating shafts are respectively provided with a first bevel gear, the second rotating shafts are respectively provided with a fourth bevel gear, a third rotating shaft is respectively arranged between the first control module and the second control module, one end of the third rotating shaft is respectively provided with a second bevel gear correspondingly engaged and connected with the first bevel gear, the other end of the third rotating shaft is respectively provided with a third bevel gear correspondingly engaged and connected with the fourth bevel gear, a rotating fourth rotating shaft is respectively arranged in the second control modules, a fifth bevel gear correspondingly meshed and connected with the third bevel gear is respectively arranged at one end of the fourth rotating shaft, and the other end of the fourth rotating shaft is respectively provided with a sixth bevel gear, and the fifth rotating shaft is respectively provided with a seventh bevel gear correspondingly meshed and connected with the sixth bevel gear.

3. The automatic dredging pipeline for sewage discharge according to claim 1, characterized in that: the sliding mechanism is characterized in that a sliding second sliding shaft is arranged between the first control module and the second control module respectively, a supporting sliding hole for supporting the sliding second sliding shaft is arranged on each of the first control module and the second control module respectively, a second gear is arranged on each of the first rotating shafts respectively, a second tooth groove which is correspondingly meshed and connected with the second gear is arranged on each of the second sliding shafts respectively, a first gear is arranged on each of the second rotating shafts respectively, a first tooth groove which is correspondingly meshed and connected with the first gear is arranged on each of the second sliding shafts respectively, a third gear is arranged on each of the fifth rotating shafts respectively, a third tooth groove which is correspondingly meshed and connected with the third gear is arranged on each of the second sliding shafts respectively, and the second sliding shafts and the supporting sliding holes are arranged in a square shape respectively.

4. The automatic dredging pipeline for sewage discharge according to claim 1, characterized in that: the pipeline body is connected with first connecting pipes respectively, the row pipes are connected with second connecting pipes corresponding to the first connecting pipes respectively, the settling pipe is clamped between the first connecting pipes and the second connecting pipes, and two ends of the settling pipe are connected to the first connecting pipes and the second connecting pipes respectively through threaded connecting sleeves.

5. The automatic dredging pipeline for sewage discharge according to claim 1, characterized in that: the connecting mechanism comprises a fifth rotating shaft, a connecting rotating shaft, a first sliding hole, a first sliding shaft, a first spring, a connecting sliding shaft, a supporting sliding groove, a second sliding shaft, a second control module and a third sliding shaft.

6. The automatic dredging pipeline for sewage discharge according to claim 1, characterized in that: and sealing gaskets are respectively arranged at the outer edges of the first blocking plate and the second blocking plate.

7. The automatic dredging pipeline for sewage discharge according to claim 1, characterized in that: the settling pipe is arranged at the bottom of the pipeline body.

8. The application of the automatic dredging pipeline for sewage disposal according to claim 1, wherein: in the process of circulating sewage in the inner cavity of the pipeline, a large amount of impurities are mixed in the sewage, and when the impurities in the sewage are further precipitated to the bottom of the inner cavity of the pipeline, the bottom of the inner cavity of the pipeline can be precipitated with sludge;