CN216383630U - Underground pipeline automatic detection anti-blocking system - Google Patents

Abstract

An automatic detection anti-blocking system for underground pipelines comprises a detection module, an alarm module and a monitoring module, wherein the detection module comprises a first water level gauge, a first flow rate gauge, a second water level gauge and a second flow rate gauge, and the first water level gauge and the second water level gauge are arranged on the underground pipelines at intervals; the alarm module comprises a supporting pipe, a first sensor, a first water drainage frame, a first floating block, a second sensor, a second water drainage frame and a second floating block, wherein the supporting pipe is connected with the top of the underground pipeline, the first sensor and the second sensor are installed in the supporting pipe at intervals, the first floating block triggers the first sensor, and the second floating block is used for triggering the second sensor. The underground pipeline automatic detection anti-blocking system measures water level through a first water level meter and a second water level meter, the first flow velocity meter and the second flow velocity meter measure flow velocity, and when the water level difference and the flow velocity difference reach a preset threshold value, a monitoring module feeds back blocking information; when the first floating block triggers the first sensor or the second floating block triggers the second sensor, the monitoring module feeds back alarm information.

Description

Underground pipeline automatic detection anti-blocking system

Technical Field

The utility model relates to the technical field of municipal equipment, in particular to an automatic detection and anti-blocking system for underground pipelines.

Background

In the municipal drainage field, underground drainage pipelines are the most common and common drainage facilities and have the functions of collecting and discharging domestic sewage and rainwater of residents. However, in the use process, sundries (such as plastic bags and chippings) mixed in the rainwater often cause the silting in the drainage pipeline, so that the urban drainage system cannot work according to the designed preset capacity, and the urban drainage function is seriously influenced. Therefore, monitoring of municipal drainage system fouling is essential.

At present, a drainage system generally includes a plurality of interconnected drainage pipes buried underground, and a gully communicating with the drainage pipes for receiving rainwater. Current drainage system lacks the monitoring to the silt condition, waits to discover usually when sewage flows back from the inlet for stom water, moreover, if there is the jam, in case a large amount of precipitation appear, serious waterlogging appears just easily to influence urban resident's normal life.

SUMMERY OF THE UTILITY MODEL

Therefore, the underground pipeline automatic detection anti-blocking system is convenient to use.

An underground pipeline automatic detection anti-blocking system comprises a detection module, an alarm module and a monitoring module, wherein the detection module comprises a first water level gauge, a first flow rate gauge, a second water level gauge and a second flow rate gauge, the first water level gauge and the second water level gauge are arranged on an underground pipeline at intervals, the first flow rate gauge is arranged on one side of the first water level gauge, and the second flow rate gauge is arranged on one side of the second water level gauge; alarm module includes stay tube, first sensor, first hydrophobic frame, first floating block, second sensor, the hydrophobic frame of second and the floating block of second, the stay tube is connected the top of underground piping, first sensor with the second sensor interval install in the stay tube, first hydrophobic frame with the hydrophobic frame interval of second is connected the stay tube, first floating block install in first hydrophobic frame, first floating block is used for triggering first sensor, the floating block of second install in the hydrophobic frame of second, the floating block of second is used for triggering the second sensor, first fluviograph first speedgraph second fluviograph second speedgraph first sensor and second sensor all with monitoring module signal connection.

In one embodiment, the detection module further comprises a first bracket and a second bracket, and the first bracket and the second bracket are both fixedly installed on the inner wall of the underground pipeline; the first flow meter is mounted on the first support and the second flow meter is mounted on the second support.

In one embodiment, the first water level meter, the first flow meter, the second water level meter, the second flow meter, the first sensor, the first water drainage frame, the first floating block, the second sensor, the second water drainage frame and the second floating block are all multiple and are arranged in a one-to-one correspondence manner; the first water level gauge and the second water level gauge are arranged in a staggered mode.

In one embodiment, the first hydrophobic framework and the second hydrophobic framework are both net structures.

In one embodiment, the underground pipeline drainage device further comprises a drainage module, wherein the drainage module comprises a first mounting frame, a first drainage pump, a second mounting frame and a second drainage pump, the first mounting frame and the second mounting frame are fixedly mounted at the top of the underground pipeline at intervals, the first mounting frame is mounted between the first drainage frame and the second drainage frame, the first drainage pump is mounted on the first mounting frame, the second drainage pump is mounted on the second mounting frame, and the second drainage pump is mounted on one side, away from the first drainage frame, of the second drainage frame.

In one embodiment, the drainage module further includes a first water inlet pipe, a first drainage pipe, a second water inlet pipe and a second drainage pipe, the first water inlet pipe is connected to one end of the first drainage pump close to the first hydrophobic rack, the first drainage pipe is connected to one end of the first drainage pump close to the second hydrophobic rack, the second water inlet pipe is connected to one end of the second drainage pump close to the second hydrophobic rack, and the second drainage pipe is connected to one end of the second drainage pump far from the second hydrophobic rack.

In one embodiment, the water level meter further comprises a power supply module, the power supply module comprises a fixing frame and a solar panel connected with the fixing frame, and the power supply module is electrically connected with the first water level meter, the first flow rate meter, the second water level meter, the second flow rate meter, the first sensor and the second sensor respectively.

In one embodiment, the detection module further comprises a first GPS device and a second GPS device, the first GPS device is installed at one side of the first water level gauge, and the second GPS device is installed at one side of the second water level gauge.

In one embodiment, the monitoring module comprises a display, an operation table and a controller, the controller is electrically connected with the display, and the first water level meter, the first flow rate meter, the second water level meter, the second flow rate meter, the first sensor and the second sensor are in signal connection with the controller.

In one embodiment, the alarm module further comprises an alarm, the alarm is mounted on the operating console, and the alarm is in signal connection with the controller.

Compared with the prior art, the utility model has the following beneficial effects:

the underground pipeline automatic detection anti-blocking system measures the water levels of different places of the underground pipeline through the first water level meter and the second water level meter, the first flow velocity meter and the second flow velocity meter measure the flow velocity of the different places of the underground pipeline, and when the water level difference and the flow velocity difference reach the preset threshold value, the monitoring module feeds back blocking information; when the first floating block triggers the first sensor or the second floating block triggers the second sensor, the monitoring module feeds back alarm information; the silting condition of the underground pipeline can be found in time, and related personnel can maintain the pipeline conveniently.

Drawings

FIG. 1 is a schematic structural diagram of an underground pipe automatic detection anti-blocking system according to a preferred embodiment of the present invention;

FIG. 2 is a schematic structural diagram of a support tube, a first sensor, a first drainage rack, a first floating block and an underground pipeline in the automatic detection and anti-blocking system for underground pipelines shown in FIG. 1;

fig. 3 is a schematic diagram of the automatic detection anti-blocking system for the underground pipeline shown in fig. 1.

Reference is made to the accompanying drawings in which:

the underground pipeline automatic detection anti-blocking system 100;

the device comprises a detection module 10, a first water level gauge 11, a first flow meter 12, a second water level gauge 13, a second flow meter 14, a first GPS (global positioning system) device 15, a second GPS device 16, an alarm module 20, a support pipe 21, a first sensor 22, a first water drainage frame 23, a first floating block 24, a second floating block 25 and an alarm 26;

the solar water heater comprises a monitoring module 30, a display 31, an operation table 32, a drainage module 40, a first mounting frame 41, a first drainage pump 42, a second mounting frame 43, a second drainage pump 44, a first water inlet pipe 45, a first drainage pipe 46, a second water inlet pipe 47, a second drainage pipe 48, a power supply module 50, a fixing frame 51, a solar panel 52 and an underground pipeline 90.

Detailed Description

In order that the utility model may be more fully understood, reference will now be made to the following description. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

It will be understood that when an element is referred to as being "secured to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. When the number of an element is referred to as "a plurality," it can be any number of two or more. The terms "vertical," "horizontal," "left," "right," and the like as used herein are for illustrative purposes only and do not represent the only embodiments.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used herein in the description of the utility model is for the purpose of describing particular embodiments only and is not intended to be limiting of the utility model. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.

Referring to fig. 1 to 3, an underground pipe automatic detection anti-blocking system 100 according to a preferred embodiment of the present invention includes a detection module 10, an alarm module 20 and a monitoring module 30, wherein the detection module 10 includes a first water level meter 11, a first flow meter 12, a second water level meter 13 and a second flow meter 14, the alarm module 20 includes a support tube 21, a first sensor 22, a first water draining frame 23, a first floating block 24, a second sensor, a second water draining frame and a second floating block 25, the underground pipe automatic detection anti-blocking system 100 measures water levels of different places of an underground pipe 90 through the first water level meter 11 and the second water level meter 13, the first flow meter 12 and the second flow meter 14 measure flow rates of the different places of the underground pipe 90, and the monitoring module 30 feeds back blocking information when a difference between a water level and a difference between the flow rates reaches a preset threshold value; when the first floating block 24 triggers the first sensor 22 or the second floating block 25 triggers the second sensor, the monitoring module 30 feeds back alarm information; the silting condition of the underground pipeline 90 can be found in time, and related personnel can maintain the pipeline conveniently.

As shown in fig. 1, the detection module 10 includes a first water level gauge 11, a first flow meter 12, a second water level gauge 13 and a second flow meter 14, wherein the first water level gauge 11 and the second water level gauge 13 are arranged on the underground pipe 90 at intervals, the first flow meter 12 is arranged on one side of the first water level gauge 11, and the second flow meter 14 is arranged on one side of the second water level gauge 13; the detection module 10 further includes a first bracket (not shown) and a second bracket (not shown), both of which are fixedly mounted on the inner wall of the underground pipe 90; the first odometer 12 is mounted on a first support and the second odometer 14 is mounted on a second support. Optionally, the first odometer 12 is positioned at 1/4 from the bottom of the underground conduit 90 by a first bracket; a second odometer 14 is positioned at 1/4 from the bottom of the underground conduit 90 by a second bracket to eliminate the effects of wall stiction on the odometer. The detection module 10 further includes a first GPS device 15 and a second GPS device 16, the first GPS device 15 being installed at one side of the first water level gauge 11, and the second GPS device 16 being installed at one side of the second water level gauge 13 for location. Furthermore, the number of the first water level meters 11, the first flow rate meters 12, the second water level meters 13, the second flow rate meters 14, the first GPS devices 15 and the second GPS devices 16 is multiple and are arranged in a one-to-one correspondence manner; the first water level gauge 11 and the second water level gauge 13 are arranged in a staggered manner and distributed at different positions of the pipeline.

As shown in fig. 1 and 2, the alarm module 20 includes a support pipe 21, a first sensor 22, a first hydrophobic frame 23, a first floating block 24, a second sensor (not shown), a second hydrophobic frame (not shown), and a second floating block 25, wherein the support pipe 21 is connected to the top of the underground pipeline 90, the first sensor 22 and the second sensor are installed in the support pipe 21 at intervals, the first hydrophobic frame 23 and the second hydrophobic frame are connected to the support pipe 21 at intervals, the first floating block 24 is installed on the first hydrophobic frame 23, the first floating block 24 is used for triggering the first sensor 22, the second floating block 25 is installed on the second hydrophobic frame, and the second floating block 25 is used for triggering the second sensor, optionally, the first sensor 22 and the second sensor are both distance sensors, and when the first floating block 24 abuts against the first sensor 22, the first touch sensor 22 is triggered; the first hydrophobic frame 23 and the second hydrophobic frame are both net structures. Further, the first sensor 22, the first hydrophobic frame 23, the first floating block 24, the second sensor, the second hydrophobic frame, and the second floating block 25 are all provided in a plurality and are arranged in a one-to-one correspondence manner. The alarm module 20 further comprises an alarm 26, and the first water level gauge 11, the first flow meter 12, the second water level gauge 13, the second flow meter 14, the first sensor 22, the second sensor and the alarm 26 are in signal connection with the monitoring module 30; optionally, the alarm 26 is an audible and visual alarm. When the water level of the underground pipeline 90 continuously rises, the first floating block 24 triggers the first sensor 22 along with the rising of the water level, or the second floating block 25 triggers the second sensor along with the rising of the water level, the monitoring module 30 receives a signal of the first sensor 22 or information of the second sensor to trigger the alarm 26, or when the monitoring module 30 detects that the blockage occurs, the monitoring module 30 also triggers the alarm 26 to remind an operator of timely processing.

As shown in fig. 1, the monitoring module 30 includes a display 31, an operation console 32 and a controller (not shown), the display 31 is mounted on the operation console 32, and the controller is electrically connected to the display 31; optionally, the alarm 26 is mounted to the console 32; further, the first water level gauge 11, the first flow meter 12, the second water level gauge 13, the second flow meter 14, the first GPS device 15, the second GPS device 16, the first sensor 22, the second sensor and the alarm 26 are all in signal connection with the controller.

As shown in fig. 1, the automatic underground pipeline detection and anti-blocking system 100 further includes a drainage module 40, the drainage module 40 includes a first mounting frame 41, a first drainage pump 42, a second mounting frame 43 and a second drainage pump 44, the first mounting frame 41 and the second mounting frame 43 are fixedly mounted on the top of the underground pipeline 90 at intervals, the first mounting frame 41 is mounted between the first drainage frame 23 and the second drainage frame, the first drainage pump 42 is mounted on the first mounting frame 41, the second drainage pump 44 is mounted on the second mounting frame 43, and the second drainage pump 44 is mounted on the second drainage frame on the side away from the first drainage frame 23; optionally, the first drain pump 42 and the second drain pump 44 are both in signal connection with the controller. In one embodiment, the drainage module 40 further includes a first water inlet pipe 45, a first drainage pipe 46, a second water inlet pipe 47 and a second drainage pipe 48, the first water inlet pipe 45 is connected to one end of the first drainage pump 42 close to the first drainage rack 23, the first drainage pipe 46 is connected to one end of the first drainage pump 42 close to the second drainage rack, the second water inlet pipe 47 is connected to one end of the second drainage pump 44 close to the second drainage rack, and the second drainage pipe 48 is connected to one end of the second drainage pump 44 far from the second drainage rack. When the first floating block 24 triggers the first sensor 22 and the second floating block 25 does not trigger the second sensor, the blockage between the first floating block 24 and the second floating block 25 is proved, the controller controls the first water pump to start, and water on one side of the first floating block 24 is pumped and regulated towards the direction of the second floating block 25 through the first water pump to drain water in time; similarly, a jam between the first float 24 and the second float 25 is evidenced when the first float 24 does not activate the first sensor 22 and the second float 25 activates the second sensor.

As shown in fig. 1, the underground pipe automatic detection anti-blocking system 100 further includes a power supply module 50, the power supply module 50 includes a fixing frame 51, a solar panel 52 connected to the fixing frame 51, and a storage battery (not shown) electrically connected to the solar panel 52, and the storage battery is electrically connected to the first water level gauge 11, the first flow meter 12, the second water level gauge 13, the second flow meter 14, the first sensor 22, the second sensor, the first GPS receiver 15, the second GPS receiver 16, the alarm 26, the display 31, the first drain pump 42, and the second drain pump 44, respectively. Optionally, the solar panels 52 are pyramid-shaped to receive solar energy from different directions, thereby improving the utilization of solar energy.

During the use, measure the water level of underground piping 90 different places through first fluviograph 11 and second fluviograph 13, first velocity of flow meter 12 and second velocity of flow meter 14 measure the velocity of flow of underground piping 90 different places, when the difference of water head and velocity of flow all reach and predetermine the threshold value, prove to have the jam condition, discern the position that takes place to block up through first GPS ware 15 and second GPS ware 16, controller feedback takes place the position information of jam to display 31, simultaneously, controller control alarm 26 starts, in order to remind operating personnel in time to maintain, and, through the dual judgement of water level and velocity of flow, reduce the condition of wrong report. When underground piping 90's water level lasted rising, first floater 24 triggered first sensor 22, and when second floater 25 did not trigger the second touch sensor, it was blockked up to prove to exist between first floater 24 and the second floater 25, and the controller triggered alarm 26 reminds operating personnel in time to handle, and simultaneously, the first water pump of controller control starts, draws the accent toward second floater 25 direction through the water of first water pump with first floater 24 one side, in time the drainage. Similarly, a jam between the first float 24 and the second float 25 is evidenced when the first float 24 does not activate the first sensor 22 and the second float 25 activates the second sensor.

The underground pipeline automatic detection anti-blocking system 100 measures the water levels of different places of the underground pipeline 90 through the first water level meter 11 and the second water level meter 13, the first flow velocity meter 12 and the second flow velocity meter 14 measure the flow velocities of the different places of the underground pipeline 90, and when the water level difference and the flow velocity difference reach the preset threshold values, the monitoring module 30 feeds back blocking information; when the first floating block 24 triggers the first sensor 22 or the second floating block 25 triggers the second sensor, the monitoring module 30 feeds back alarm information; the silting condition of the underground pipeline 90 can be found in time, and related personnel can maintain the pipeline conveniently.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only express several embodiments of the present invention, and the description thereof is more specific and detailed, but not construed as limiting the scope of the utility model. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims (10)

1. An underground pipeline automatic detection anti-blocking system is characterized by comprising a detection module, an alarm module and a monitoring module, wherein the detection module comprises a first water level gauge, a first flow rate gauge, a second water level gauge and a second flow rate gauge, the first water level gauge and the second water level gauge are arranged on an underground pipeline at intervals, the first flow rate gauge is arranged on one side of the first water level gauge, and the second flow rate gauge is arranged on one side of the second water level gauge; alarm module includes stay tube, first sensor, first hydrophobic frame, first floating block, second sensor, the hydrophobic frame of second and the floating block of second, the stay tube is connected the top of underground piping, first sensor with the second sensor interval install in the stay tube, first hydrophobic frame with the hydrophobic frame interval of second is connected the stay tube, first floating block install in first hydrophobic frame, first floating block is used for triggering first sensor, the floating block of second install in the hydrophobic frame of second, the floating block of second is used for triggering the second sensor, first fluviograph first speedgraph second fluviograph second speedgraph first sensor and second sensor all with monitoring module signal connection.

2. The automatic detection and anti-blocking system for the underground pipeline according to claim 1, wherein the detection module further comprises a first bracket and a second bracket, and the first bracket and the second bracket are both fixedly installed on the inner wall of the underground pipeline; the first flow meter is mounted on the first support and the second flow meter is mounted on the second support.

3. The automatic detection and anti-blocking system for the underground pipeline as claimed in claim 1, wherein the number of the first water level gauge, the first flow velocity gauge, the second water level gauge, the second flow velocity gauge, the first sensor, the first drainage frame, the first floating block, the second sensor, the second drainage frame and the second floating block is multiple and is arranged in a one-to-one correspondence manner; the first water level gauge and the second water level gauge are arranged in a staggered mode.

4. The automatic detection and anti-blocking system for underground pipelines according to claim 1, wherein the first hydrophobic rack and the second hydrophobic rack are both of a mesh structure.

5. The automatic detection and anti-blocking system for underground pipelines according to claim 1, further comprising a drainage module, wherein the drainage module comprises a first mounting frame, a first drainage pump, a second mounting frame and a second drainage pump, the first mounting frame and the second mounting frame are fixedly mounted on the top of the underground pipeline at intervals, the first mounting frame is mounted between the first drainage frame and the second drainage frame, the first drainage pump is mounted on the first mounting frame, the second drainage pump is mounted on the second mounting frame, and the second drainage pump is mounted on the side of the second drainage frame away from the first drainage frame.

6. The automatic detection and anti-blocking system for underground pipelines according to claim 5, wherein the drainage module further comprises a first water inlet pipe, a first drainage pipe, a second water inlet pipe and a second drainage pipe, the first water inlet pipe is connected with one end of the first drainage pump close to the first drainage rack, the first drainage pipe is connected with one end of the first drainage pump close to the second drainage rack, the second water inlet pipe is connected with one end of the second drainage pump close to the second drainage rack, and the second drainage pipe is connected with one end of the second drainage pump far from the second drainage rack.

7. The automatic detection and anti-blocking system for the underground pipeline as claimed in claim 1, further comprising a power supply module, wherein the power supply module comprises a fixing frame and a solar panel connected with the fixing frame, and the power supply module is electrically connected with the first water level meter, the first flow rate meter, the second water level meter, the second flow rate meter, the first sensor and the second sensor respectively.

8. The automatic detection and anti-blocking system for underground pipelines according to claim 1, wherein the detection module further comprises a first GPS device and a second GPS device, the first GPS device is installed at one side of the first water level gauge, and the second GPS device is installed at one side of the second water level gauge.

9. The automatic detection and anti-blocking system for underground pipelines according to claim 1, wherein the monitoring module comprises a display, an operation desk and a controller, the controller is electrically connected with the display, and the first water level meter, the first flow rate meter, the second water level meter, the second flow rate meter, the first sensor and the second sensor are in signal connection with the controller.

10. The automatic detection and anti-blocking system for underground pipelines according to claim 9, wherein the alarm module further comprises an alarm, the alarm is mounted on the console, and the alarm is in signal connection with the controller.

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