CN113063102B

CN113063102B - Pipeline leakage leak source monitoring mechanism

Info

Publication number: CN113063102B
Application number: CN202110475363.0A
Authority: CN
Inventors: 沈劼昕; 马丽莉; 林舒涵; 王新晨
Original assignee: Yizhi Technology Huzhou Co ltd
Current assignee: Yizhi Technology Huzhou Co ltd
Priority date: 2021-04-29
Filing date: 2021-04-29
Publication date: 2022-12-27
Anticipated expiration: 2041-04-29
Also published as: CN113063102A

Abstract

The invention discloses a pipeline leakage and leak point monitoring mechanism, and aims to provide a pipeline leakage and leak point monitoring mechanism which is convenient to mount and dismount. Including PC end, cloud server, GPS, sensing device and data transmission line, the PC end pass through wireless network and be connected with cloud server, sensing device includes sensing component and power supply ware, sensing component passes through data transmission line and is connected with the power supply ware electricity, cloud server pass through wireless network and be connected with cloud server and sensing component respectively, sensing component is equipped with a plurality of parts, can install in a flexible way and dismantle, be convenient for with being connected of pipeline. The invention has the beneficial effects that: the sensor is convenient to install, disassemble and replace, the connection mode is diversified, each part is stably connected, the temperature can be kept constant, the temperature can be controlled, the erosion of water to the sensor can be effectively controlled, the service life is long, the structure is simple, the operation is convenient, and the universality is strong.

Description

Pipeline leakage leak source monitoring mechanism

Technical Field

The invention relates to the related technical field of monitoring instruments, in particular to a pipeline leakage point monitoring mechanism.

Background

Pipeline safety is the prerequisite of pipeline transportation, because the third party construction causes to have the destruction of pipeline, pipeline self ageing and corruption, external traffic and large building to pipeline production overload pressure, sudden impact and installation nonconformity standard regulation the reason fracture or damage, lead to leaking occasionally to take place. The leakage of various pipelines not only seriously affects the rapid development of national economy, but also brings great harm to human health, natural environment, social environment and pipeline systems. Therefore, the research on the pipeline leakage fault diagnosis technology has remarkable social and economic benefits. With the development of national economy, the laying of various pipelines is more and more extensive and more complicated, and the general trend is that a large number of pipelines are buried underground and distributed in a net shape, which brings great difficulty to the leakage monitoring work of a pipe network.

Disclosure of Invention

The invention provides a pipeline leakage point monitoring mechanism which is convenient to mount and dismount in order to overcome the defect that a pipeline leakage point monitoring instrument is difficult to mount and dismount in the prior art.

In order to achieve the purpose, the invention adopts the following technical scheme:

the utility model provides a pipeline leakage leak source monitoring mechanism, installs on the pipeline, characterized by, including PC end, cloud server, GPS, sensing device and data transmission line, the PC end pass through wireless network and be connected with cloud server, sensing device includes sensing component and power supply ware, sensing component passes through data transmission line and is connected with the power supply ware electricity, cloud server pass through wireless network and be connected with cloud server and sensing component respectively.

The PC end is connected with the cloud server through a wireless network, the sensing device comprises a sensing assembly and a power supply device, the sensing assembly is electrically connected with the power supply device through a data transmission line, the cloud server is respectively connected with the cloud server and the sensing assembly through the wireless network, the PC end is connected with the cloud server through the wireless network to achieve remote communication, the real-time monitoring function of data is achieved, the GPS is connected with the sensing assembly to achieve leak source accurate positioning and time synchronization functions, the GPS is connected with the cloud server to send positioning, the sensing assembly receives sound waves, transmits the sound waves to the cloud server through a wireless sound wave transmitter after being collected and processed, the cloud server performs centralized integration on the data, storage, the sensing assembly is provided with a plurality of parts, the sensor can be flexibly mounted and dismounted, and is convenient to be connected with a pipeline.

Preferably, a connecting sleeve is arranged on the sensing assembly and comprises a circular ring and a groove seat matched with the power supply device, the circular ring is fixed on the sensing assembly, the power supply device is installed in the groove seat, the power supply device is connected with the sensing assembly through the connecting sleeve, the connecting sleeve facilitates physical fixation of the power supply device and the sensing generator, so that the electric connection distance is shortened, the circular ring can be adjusted according to the actual shape of the sensing assembly, and the groove seat can better fix the power supply device.

As preferred, sensing element includes the casing, the inside of casing is equipped with the cavity, the upper end of casing is equipped with interface one, interface one and the cavity intercommunication in the casing, the cavity in and arrange the below of interface one in and be equipped with the converter, the converter right side is equipped with the treater, the converter is connected with the treater electricity, a treater and interface electricity be connected, converter and treater electricity be connected, wireless sound wave generator is equipped with to the upper end of treater, wireless sound wave generator is connected with the treater electricity, and the converter is used for the enlargeing of diffuse reflection wave, and the treater is used for the processing of diffuse reflection wave, and diffuse reflection wave cloud ware is given for cloud ware to wireless sound wave generator after handling the treater, and such design is convenient for carry out preliminary rough processing to the diffuse reflection wave, is convenient for provide data to cloud ware.

Preferably, the wireless sound wave generator penetrates through the shell and is arranged outside the shell, the processor is provided with a diffuse reflection collector below, the processor is electrically connected with the diffuse reflection collector, the infrasonic wave emitter is arranged below the diffuse reflection collector and electrically connected with the processor, a timer is arranged on the left side of the diffuse reflection collector and electrically connected with the processor, the infrasonic wave emitter emits infrasonic waves into the pipeline, the diffuse reflection wave collector is used for receiving diffuse reflection waves formed when the infrasonic waves encounter leak points in the pipeline, and the timer is used for timing the whole sound wave generation process, so that the working time of the sensing device can be conveniently recorded.

Preferably, be equipped with display and interface two in the power supply ware, the top of power supply ware is equipped with the cavity, the display install in the cavity, display below be equipped with the power, the display be connected with the power electricity, the power pass through interface two and be connected with interface one electricity, the display is used for showing the actual electric quantity of power, is convenient for in time change, the power is used for providing the energy, interface two utilizes data transmission line and interface one to be connected, realizes that the power supply ware provides the power supply for sensing component for sensing device normally works.

Preferably, a base is arranged below the shell, the base is in threaded connection with the shell, the base comprises a magnet, a plurality of thermostatic plates and a plurality of support frames, a plurality of trapezoidal blocks are mounted at the bottom of each thermostatic plate, grooves corresponding to the trapezoidal blocks are formed in the base, the thermostatic plates are connected with the base in an inserting mode through the grooves and the trapezoidal blocks, holes corresponding to the support frames are formed in the base, the support frames penetrate through the holes and are connected with the base in a clamped mode, the magnet is connected with the base through the triangular grooves, the thermostatic plates and the support frames are evenly distributed on the outer sides of the magnet at intervals, the base is in threaded connection with the shell, the thermostatic plates and the base are convenient to mount and dismount, the thermostatic plates are better fixed with the base in an inserting mode, the support frame is connected with the base in a clamped mode, connection stability of the support frame and the base is convenient to enhance, the support frame is convenient to fix the sensing plug-in connection with the pipeline, the magnet is easy to disassemble due to triangular design, connection stability of the base and the pipeline is increased, and replacement of the sensing assembly and the pipeline is convenient to replace parts.

Preferably, the thermostatic plate is provided with a plurality of heaters and a plurality of temperature sensors, the thermostatic plate is further provided with a cross groove, the heaters are connected with the thermostatic plate through the cross groove, the thermostatic plate is provided with a plurality of strip grooves, notches are formed in the strip grooves, the temperature sensors are connected with the thermostatic plate through the strip grooves and the notches in a clamped mode, the heaters are connected with the thermostatic plate more stably through the connection mode of the cross groove, the strip grooves are designed to facilitate installation of the temperature sensors in disassembly, and the connection stability of each part and the thermostatic plate is improved through the design, so that the disassembly, the assembly and the replacement are facilitated.

As preferred, be equipped with the round hole in the middle of the thermostated plate, be equipped with the fan box in the round hole, the fan box install in the round hole, the fan is equipped with in the fan box, the fan is connected with the treater electricity through interface one, the fan box outside is all arranged in to heater and temperature-sensing ware, heater and temperature-sensing ware all be connected with the treater electricity, the thermostated plate is used for balanced sensing generator inside temperature, the temperature-sensing ware is used for perception sensing assembly inside temperature to in time with information transfer for the treater, the treater gives the heater with intensification information transmission again, the heater heats up work, when high temperature information was received to the temperature-sensing ware, give the treater with information transfer, the treater is handled the back and is given the fan with cooling information transmission, the work of cooling is carried out to the fan, the design of round hole is convenient for the installation of fan box, the design of electricity connection is convenient for whole sensing device to form electric loop, such circuit design is convenient for the work that the treater integrates each part of processing base.

As preferred, the support frame include support frame top, support frame pipe one, support frame pipe two and support frame bottom, the top threaded connection of support frame top and support frame pipe one, the diameter of support frame pipe one is greater than the diameter of support frame pipe two, the bottom of support frame pipe one is equipped with the cavity, the position department that just places the cavity place in on the support frame pipe one is equipped with two corresponding sliding trays, the cavity pass through the outside intercommunication of sliding tray and support frame pipe one, be equipped with the tight set bolt on the one end side that support frame pipe two is connected with support frame pipe one, support frame pipe two is equipped with the one end of tight set bolt and arranges in the cavity of support frame pipe one in, the tight set bolt pass the outside of arranging support frame pipe one behind the sliding tray, be equipped with the tight set nut on the tight set bolt in the support frame pipe one outside, tight set bolt and tight set nut threaded connection, the other end and the support frame bottom of support frame pipe are connected, support frame pipe one arrange in the downthehole of base, the simple convenient and convenient of the connected mode of support frame top and support frame pipe one, the installation of sliding tray is convenient for the quick detachable length direction, the tight set bolt is convenient for change of the support frame pipe, the design, the use life of the instrument is used for the tight set nut.

As preferred, the support frame top from the top down includes circular cone portion, cylinder portion and disc portion in proper order, the inside cavity on support frame top, be equipped with a plurality of round holes on the lateral surface on support frame top, round hole and the inside intercommunication in support frame top, the centre of support frame pipe one and support frame pipe two all is equipped with the cavity and is equipped with the stone that absorbs water, the shape of support frame bottom is conical, be equipped with the passageway that absorbs water on the support frame bottom, the inside on support frame top, the cavity of the inside of support frame pipe one, the cavity of the inside of support frame pipe two and the passageway that absorbs water of support frame bottom communicate in proper order, and the round hole is used for communicateing the inside and outside gas exchange of sensing assembly and for the moisture that the inside and the outside produced of sensing assembly provides the passageway, and the stone that absorbs water is used for absorbing the moisture that sensing assembly inside and external get into, and the support frame bottom is conical be convenient for inserting the underground better, and the most advanced moisture that stores in order to discharge the stone that absorbs water of opening form prevents the erosion of water to sensor generator, and such design is convenient for providing good air and moisture circulation channel for sensing assembly, increase of service life.

The invention has the beneficial effects that: the sensor is convenient to install, disassemble and replace, the connection mode is diversified, each part is stably connected, the temperature can be kept constant, the temperature can be controlled, the erosion of water to the sensor can be effectively controlled, the service life is long, the structure is simple, the operation is convenient, and the universality is strong.

Drawings

FIG. 1 is a schematic diagram of the system operation of the present invention;

FIG. 2 is a schematic structural view of the present invention;

FIG. 3 is a cross-sectional view of the sensor generator;

FIG. 4 is a cross-sectional view of the power supply;

FIG. 5 is a schematic view of the base;

FIG. 6 is a schematic view of the structure of the thermostatic plate;

FIG. 7 is a schematic view of the support frame;

fig. 8 is a cross-sectional view of the support stand.

In the figure: the system comprises a PC terminal 1, a cloud server 2, a GPS3, a sensing assembly 4, a power supply 5, a leakage point 6, a pipeline 7, a data transmission line 8, a connecting sleeve 9, a connector 10, a first interface 11, a converter 12, a wireless sound wave generator 13, a processor 14, a diffuse reflection collector 15, a shell 16, a base 17, an infrasonic wave emitter 18, a timer 19, a display 20, a power supply 21, a second interface 22, a thermostatic plate 23, a heater 24, a fan 25, a fan box 26, a temperature sensor 27, a support frame 28, a magnet 29, a cross groove 30, a notch 31, a strip groove 32, a trapezoidal block 33, a support frame top end 34, a support frame first pipe 35, a sliding groove 36, a fastening nut 37, a fastening bolt 38, a support frame second pipe 39 and a support frame bottom end.

Detailed Description

The invention is further described with reference to the following figures and detailed description.

As shown in figure 1, the pipeline leakage and leakage point monitoring system comprises a PC end 1, a cloud server 2, a GPS3, a sensing device and a data transmission line 8, wherein the PC end 1 is connected with the cloud server 2 through a wireless network, the sensing device comprises a sensing component 4 and a power supply 5, the sensing component 4 is electrically connected with the power supply 5 through the data transmission line 8, the cloud server 2 is connected with the sensing component 4 through the wireless network, and the GPS3 is respectively connected with the cloud server 2 and the sensing component 4 through the wireless network. The sensing assembly 4 is provided with a connecting sleeve 9, the connecting sleeve 9 comprises a circular ring and a groove seat matched with the power supplier 5, the circular ring is fixed on the sensing assembly 4, the power supplier 5 is installed in the groove seat, and the power supplier 5 is connected with the sensing assembly 4 through the connecting sleeve 9.

The sensing assembly 4 comprises a shell 15, a cavity is arranged in the shell 15, a first interface 10 is arranged at the upper end of the shell 15, the first interface 10 is communicated with the cavity in the shell 15, a converter 11 is arranged below the first interface 10 in the cavity, a processor 13 is arranged on the right side of the converter 11, the processor 13 is electrically connected with the first interface 10, the converter 11 is electrically connected with the processor 13, a wireless sound wave generator 12 is arranged at the upper end of the processor 13, and the wireless sound wave generator 12 is electrically connected with the processor 13. The wireless sound wave generator 12 penetrates through the shell 15 and then is arranged outside the shell 15, the diffuse reflection collector 14 is arranged below the processor 13, the processor 13 is electrically connected with the diffuse reflection collector 14, the infrasonic wave emitter 17 is arranged below the diffuse reflection collector 14, the infrasonic wave emitter 17 is electrically connected with the processor 13, the timer 18 is arranged on the left side of the diffuse reflection collector 14, and the timer 18 is electrically connected with the processor 13. The power supply device 5 is internally provided with a display 19 and a second interface 21, a cavity is arranged above the power supply device 5, the display 19 is arranged in the cavity, a power supply 20 is arranged below the display 19, the display 19 is electrically connected with the power supply 20, and the power supply 20 is electrically connected with the first interface 10 through the second interface 21.

The below of casing 15 is equipped with base 16,

base

16 and 15 threaded connection of casing, base 16 is equipped with a magnet 28, a plurality of thermostats 22 and a plurality of support frame 27, a plurality of trapezoidal blocks 32 are equipped with to the bottom of thermostats 22, be equipped with the recess that corresponds with trapezoidal block 32 on the base 16, thermostats 22 pegs graft with base 16 through the cooperation of recess and trapezoidal block 32, be equipped with the hole that corresponds with support frame 27 on the base 16, support frame 27 passes hole and base 16 joint, the centre of base 16 is equipped with the triangular groove that corresponds with magnet 28, magnet 28 is connected with base 16 through the triangular groove, thermostats 22 and the outside of support frame 27 evenly spaced distribution at magnet 28. The thermostatic board 22 is provided with a plurality of heaters 23 and a plurality of temperature sensors 26, the thermostatic board 22 is provided with a cross slot 29, the heaters 23 are connected with the thermostatic board 22 through the cross slot 29, the thermostatic board 22 is provided with a strip slot 31, a notch 30 is arranged in the middle of the strip slot 31, and the temperature sensors 26 are clamped with the thermostatic board 22 through the strip slot 31 and the notch 30. The middle of the thermostatic plate 22 is provided with a round hole, a fan box 25 is arranged in the round hole, the fan box 25 is installed in the round hole, a fan 24 is installed in the fan box 25, the fan 24 is electrically connected with the processor 13, the heater 23 and the temperature sensor 26 are both arranged on the outer side of the fan box 25, and the heater 23 and the temperature sensor 26 are both electrically connected with the processor 13.

The supporting frame 27 comprises a supporting frame top end 33, a supporting frame round pipe I34, a supporting frame round pipe II 38 and a supporting frame bottom end 39, the supporting frame top end 33 is in threaded connection with the upper portion of the supporting frame round pipe I34, the diameter of the supporting frame round pipe I34 is larger than that of the supporting frame round pipe II 38, a cavity is formed in the bottom of the supporting frame round pipe I34, two corresponding sliding grooves 35 are formed in the position, where the cavity is located, of the supporting frame round pipe I34, the cavity is communicated with the outer side of the supporting frame round pipe I34 through the sliding grooves 35, a fastening bolt 37 is arranged on one end side face, connected with the supporting frame round pipe I34, of the supporting frame round pipe II 38, one end, provided with the fastening bolt 37, is arranged in the cavity of the supporting frame round pipe I34 after the fastening bolt 37 penetrates through the sliding grooves 35, a fastening nut 36 is arranged on the fastening bolt 37 on the outer side of the supporting frame round pipe I34, the fastening bolt 37 is in threaded connection with the fastening nut 36, the other end of the supporting frame round pipe II 38 is connected with the supporting frame bottom end 39, and the supporting frame round pipe I34 is arranged in the hole of the base 16. Support frame top 33 from the top down includes circular cone portion in proper order, cylinder portion and disc portion, the inside cavity of support frame top 33, be equipped with a plurality of round holes on the lateral surface of support frame top 33, round hole and the inside intercommunication in support frame top 33, it is equipped with the stone that absorbs water in cavity and the cavity all to be equipped with in the middle of the inside of support frame pipe 34 and support frame pipe two 38, the shape of support frame bottom 39 is conical, be equipped with the passageway that absorbs water on the support frame bottom 39, the inside on support frame top 33, the inside cavity of support frame pipe 34, the inside cavity of support frame pipe two 38 and the passageway that absorbs water of support frame bottom 39 communicate in proper order.

During installation, as shown in fig. 5, firstly, the heater 23 is inserted into the cross groove 29 on the thermostatic board 22, the temperature sensor 26 is inserted into the strip-shaped groove 31, the fan 24 is installed in the fan box 25, after all components on the thermostatic board 22 are installed, as shown in fig. 6, the thermostatic board 22 is inserted into the groove on the base 16, so that the thermostatic board 22 is connected with the base 16, as shown in fig. 7, the top end 33 of the support frame is in threaded connection with the first support frame circular tube 34, the bottom end 39 of the support frame is in threaded connection with the second support frame circular tube 38, as shown in fig. 8, the fastening bolt 37 is adjusted, the outer side of the first support frame circular tube 34 is communicated with the cavity at the bottom of the first support frame circular tube 34 by using the sliding groove 35, after the fastening bolt 37 passes through the sliding groove 35, the first support frame circular tube 34 is connected with the second support frame circular tube 38 by using the fastening bolt 37, then the fastening nut 36 is tightened, then the support frame 27 passes through the groove on the base 16 to be clamped with the base 16, and after the base 16 is installed, the base 16 is connected with the shell of the sensing assembly 4 by threads, so that the sensing assembly 4 becomes a whole; as shown in fig. 2, a power supply 5 is nested on a connecting sleeve 9, the power supply 5 is physically connected with the sensing component 4, as shown in fig. 4, a data transmission line 8 is respectively connected to an interface i 10 and an interface ii 21, so as to electrically connect the sensing component 4 with the power supply 5, the power supply 5 provides a power source for the sensing component 4, and the sensing component 4 and the power supply 5 together form a complete sensing device; and finally, connecting the sensing device with the pipeline 7, inserting the support frame 27 into the ground to adjust the length of the support frame 27 according to the actual size of the pipeline 7, placing the sensing device on the pipeline 7 after adjustment, screwing the fastening nut 36 on the fastening bolt 37, and increasing the connection stability of the sensing device and the pipeline 7 by using the magnet 28 in the sensing device.

When the pipeline leakage monitoring device is used, as shown in fig. 3, an infrasonic wave emitter 17 emits infrasonic waves to a pipeline 7, the infrasonic waves are transmitted on the wall of the pipeline 7 and in liquid and meet a leakage point 6, the infrasonic waves form diffuse reflection, a diffuse reflection collector 14 receives diffuse reflection waves and transmits the diffuse reflection waves to a processor 13, the processor 13 amplifies the diffuse reflection waves and transmits the diffuse reflection waves to a converter 11, the converter 11 performs rough filtering conversion on the diffuse reflection waves and transmits the diffuse reflection waves to a wireless sound generator 12, as shown in fig. 1, the wireless sound generator 12 transmits the diffuse reflection waves to a cloud server 2 through a wireless network, a GPS3 gives time to sensing components 4, a timer 18 times the time when the diffuse reflection waves are received, the cloud server 2 calculates the time difference when the two sensing components 4 receive the diffuse reflection waves, then feeds back the calculation result to the sensing components 4, the sensing components 4 receive information of the leakage point 6, the GPS3 accurately positions the leakage point 6, a PC end 1 monitors data in real time, and maintains the pipeline 7 by determining the position of the leakage point 6. In actual operation, the installation and the use are carried out according to the steps, and flexible adjustment can be carried out according to actual conditions.

Claims

1. A pipeline leakage leak source monitoring system is characterized by comprising a PC end (1), a cloud server (2), a GPS (3), a sensing device and a data transmission line (8), wherein the PC end (1) is connected with the cloud server (2) through a wireless network, the sensing device comprises a sensing component (4) and a power supply (5), the sensing component (4) is electrically connected with the power supply (5) through the data transmission line (8), the cloud server (2) is connected with the sensing component (4) through the wireless network, the GPS (3) is respectively connected with the cloud server (2) and the sensing component (4) through the wireless network, a connecting sleeve (9) is arranged on the sensing component (4), the connecting sleeve (9) comprises a circular ring and a groove seat matched with the power supply (5), the circular ring is fixed on the sensing component (4), the power supply (5) is arranged in the groove seat, the power supply (5) is connected with the sensing component (4) through the connecting sleeve (9), the sensing component (4) comprises a cavity (15), an interface (10) arranged in the cavity (15), and an interface (10) arranged below the shell (15) and a connector (10) is arranged in the cavity (15), the improved ultrasonic wave generator is characterized in that a processor (13) is arranged on the right side of the converter (11), the processor (13) is electrically connected with a first interface (10), the converter (11) is electrically connected with the processor (13), a wireless sound wave generator (12) is installed at the upper end of the processor (13), the wireless sound wave generator (12) is electrically connected with the processor (13), the wireless sound wave generator (12) penetrates through a shell (15) and then is arranged outside the shell (15), a diffuse reflection collector (14) is arranged below the processor (13), the processor (13) is electrically connected with the diffuse reflection collector (14), an infrasonic wave emitter (17) is installed below the diffuse reflection collector (14), the infrasonic wave emitter (17) is electrically connected with the processor (13), a timer (18) is arranged on the left side of the diffuse reflection collector (14), the timer (18) is electrically connected with the processor (13), a base (16) is arranged below the shell (15), the base (16) is in threaded connection with the shell (15), a plurality of magnets (28) and a plurality of supporting frames (22) and a plurality of trapezoidal blocks (32) are arranged on the bottom of the trapezoidal blocks (22), thermostatic board (22) pass through the cooperation of recess and trapezoidal piece (32) and peg graft with base (16), be equipped with the hole that corresponds with support frame (27) on base (16), support frame (27) pass hole and base (16) joint, the centre of base (16) is equipped with the triangular groove that corresponds with magnet (28), magnet (28) be connected with base (16) through triangular groove, thermostatic board (22) and support frame (27) even interval distribution in the outside of magnet (28), support frame (27) including support frame top (33), support frame pipe (34), support frame pipe two (38) and support frame bottom (39), the top threaded connection of support frame top (33) and support frame pipe (34), the diameter of support frame pipe (34) is greater than the diameter of support frame pipe two (38), the bottom of support frame pipe (34) is equipped with the cavity, the position department that the cavity place in on support frame one (34) and be equipped with two corresponding sliding groove (35), the cavity of support frame is equipped with the tight bolt (37) through the pipe (37) outside the pipe (34) and the tight bolt (37) connect the support frame (37) one end and be equipped with the support frame (37) intercommunication In the cavity of support frame pipe (34), holding bolt (37) pass sliding tray (35) the back and arrange the outside of support frame pipe (34) in, holding bolt (37) in the support frame pipe (34) outside on be equipped with holding nut (36), holding bolt (37) and holding nut (36) threaded connection, the other end and support frame bottom (39) of support frame pipe two (38) are connected, support frame pipe one (34) arrange the downthehole of base (16) in, support frame top (33) from the top down includes cone portion, cylinder portion and disc portion in proper order, the inside cavity of support frame top (33), be equipped with a plurality of round holes on the lateral surface of support frame top (33), round hole and the inside intercommunication of support frame top (33), all be equipped with the water absorption stone in the cavity and the cavity in the middle of the inside of support frame pipe two (34) and support frame pipe two (38), the shape of support frame bottom (39) is the conical shape, be equipped with the passageway that absorbs water on support frame bottom (39), the inside of support frame top (33), the inside of support frame pipe (34) and the cavity and the inside water absorption stone and the support frame bottom (38) and the water absorption passageway (39) and support frame pipe.

2. The pipeline leakage and leakage point monitoring system according to claim 1, wherein a display (19) and a second interface (21) are arranged in the power supply (5), a cavity is arranged above the power supply (5), the display (19) is installed in the cavity, a power supply (20) is arranged below the display (19), the display (19) is electrically connected with the power supply (20), and the power supply (20) is electrically connected with the first interface (10) through the second interface (21).

3. The pipeline leakage and leakage point monitoring system according to claim 1, wherein the thermostatic board (22) is provided with a plurality of heaters (23) and a plurality of temperature sensors (26), the thermostatic board (22) is provided with a cross slot (29), the heaters (23) are connected with the thermostatic board (22) through the cross slot (29), the thermostatic board (22) is provided with a strip-shaped slot (31), the strip-shaped slot (31) is provided with a notch (30) in the middle, and the temperature sensors (26) are connected with the thermostatic board (22) in a clamping manner through the strip-shaped slot (31) and the notch (30).

4. The pipeline leakage and leakage point monitoring system according to claim 3, wherein a circular hole is formed in the middle of the thermostatic plate (22), a fan box (25) is arranged in the circular hole, the fan box (25) is installed in the circular hole, a fan (24) is installed in the fan box (25), the fan (24) is electrically connected with the processor (13), the heater (23) and the temperature sensor (26) are both arranged on the outer side of the fan box (25), and the heater (23) and the temperature sensor (26) are both electrically connected with the processor (13).