TWM624924U - Saddle belt monitoring stopcock device - Google Patents

Abstract

A saddle-belt monitoring plug valve device, comprising: a saddle belt, a water spigot, a battery accommodating box and a pipeline monitoring component, the pipeline monitoring component senses a fluid conveying pipe located under the ground, And the pipeline monitoring information is directly wirelessly sent to a monitoring terminal device located on the ground in a manner of reducing the ground shielding through the ground exposed part of the battery accommodating box.

Description

Saddle belt monitoring plug valve device

The present invention relates to a fluid pipeline monitoring device, in particular to a saddle-belt monitoring plug valve device.

A fluid delivery pipe is a pipe used to transport fluids, among which tap water pipes are the most common. According to statistics, the leakage rate of water pipes in all counties and cities in Taiwan this year is nearly 25% at the highest and nearly 10% at the lowest. It can be seen that the water leakage rate is alarming, and it can even be said that the main culprit for water shortage in Taiwan is the leakage of the fluid delivery pipe.

In order to solve the leakage problem of the fluid delivery pipe, in the prior art, a fluid pipeline monitoring device is installed on the fluid delivery pipe to monitor the fluid delivery pipe and return information to determine whether there is any abnormal situation such as leakage. However, because the fluid delivery pipes are generally installed under the ground, the information return of the fluid pipeline monitoring device is easily shielded by the ground and cannot be carried out through wireless transmission. It is often necessary to first transmit the monitoring information to the ground through a signal line extending to the ground. on the communication station, and then hand it over to the communication station for transmission. In addition, in order to maintain the long-term operation of the fluid pipeline monitoring device, the prior art also needs to further provide a power supply device, and supply power to the fluid pipeline monitoring device through a power line extending under the ground.

Such an approach not only needs to add a communication station and power supply equipment on the ground, but also needs to connect the signal line between the communication station and the fluid pipeline monitoring device and the power supply line between the power supply equipment and the fluid pipeline monitoring device. It is more complicated, and the communication station and power supply equipment on the ground will occupy more space, and it is easy to cause obstacles to existing roads or ground facilities.

Therefore, the purpose of the present invention is to provide a saddle-belt monitoring plug valve device, which is easy to install, does not occupy floor space, and can perform good information return, so as to solve the problems of the prior art.

The technical means adopted by the present invention to solve the problems of the prior art is to provide a saddle-belt monitoring valve device for monitoring a fluid conveying pipe located under the ground. The saddle-belt monitoring valve device includes: a saddle belt, including an upper saddle belt and a lower saddle belt, the upper saddle belt and the lower saddle belt are abutted up and down to surround and fix the fluid conveying pipe between the upper saddle belt and the lower saddle belt, the upper saddle belt A plug valve communication hole is formed through the plug valve, and the plug valve communication hole is provided with an opening corresponding to a pipe wall of the fluid conveying pipe; a water diversion plug includes a water diversion plug body, a communication pipe part and a diversion pipe part. The water diversion plug body has a top opening, the communication pipe part and the diversion pipe part respectively extend from the water diversion plug body and communicate with the top opening, and the water diversion plug is arranged on the saddle to make the water diversion plug body It is connected to the fluid conveying pipe through the communication pipe portion, the valve communication hole and the pipe wall opening; and a battery accommodating box, the bottom of the battery accommodating box has a bolt assembly portion, the The top of the battery accommodating box is provided with a ground exposed portion, and the bolt assembly portion of the battery accommodating box and the ground exposed portion are separated by a predetermined box extension height to form a battery accommodating space. The extension height of the box body is set so that the battery accommodating box body is set in a way that the plug body assembly part is assembled and communicated with the top opening of the water diversion plug body and the ground exposed part is exposed to the ground for the signal in the water diverter; and a pipeline monitoring component, including a battery, a control circuit module, and at least one sensor, the battery is accommodated in the battery accommodating space, and the control circuit module is coupled to The battery, at least one of the sensor is coupled to the control circuit module through the plug assembly part, the top opening, the water diversion plug body, the communication pipe part, the plug valve communication hole and the pipe wall Opening a hole and extending into the fluid delivery pipe to sense and obtain pipeline monitoring information about the fluid delivery pipe, the pipeline monitoring information at least includes fluid pressure information in the pipe, wherein the control circuit module has an information sending unit, The information sending unit is configured to directly wirelessly send the pipeline monitoring information to a monitoring terminal device located on the ground in a manner of reducing the ground shielding through the ground exposed portion of the battery accommodating box.

An embodiment of the present invention provides a saddle-belt monitoring valve device, wherein the water diverter further includes an electric valve body driver coupled to the battery and the control circuit module, and the control circuit module has a signal receiving unit, the signal receiving unit is configured to receive a valve body control signal from above the ground in a manner of reducing shielding by the ground through the ground exposed portion of the battery accommodating box, the control circuit modulates The group controls the electric valve body driver according to the valve body control signal, and drives a valve body in the water diversion plug body by the electric valve body driver to change the water diversion adjustment position of the valve body.

In an embodiment of the present invention, a saddle-belt monitoring plug valve device is provided, wherein the pipeline monitoring component includes a plurality of the sensors, and the pipeline monitoring information sensed by the plurality of the sensors further includes One or more information among toxic substance detection information, fluid turbidity information in the pipe, pH information of the fluid in the pipe, plastic particle content information in the fluid in the pipe, and fluid flow information in the pipe.

In an embodiment of the present invention, a saddle-belt monitoring plug valve device is provided, wherein the ground-exposed portion is configured as a pavement cat-eye device.

An embodiment of the present invention provides a saddle-belt monitoring valve device, wherein the battery is a rechargeable battery, the control circuit module has a wireless charging unit, and the wireless charging unit is configured to pass the The ground-exposed portion of the battery accommodating box is inductively coupled to a wireless charging device on the ground in a manner of reducing shielding by the ground, so as to charge the rechargeable battery.

In an embodiment of the present invention, a saddle-belt monitoring plug valve device is provided, wherein the pipeline monitoring information includes pipeline leakage point information, and at least one of the sensors further includes a pipeline leakage point detector. The road leak point detector obtains the pipeline by sensing a leak detection signal sent by a detection signal transmitting unit of another saddle-belt monitoring valve device through the fluid conveying pipe with a detection signal receiving unit. leak point information.

In an embodiment of the present invention, a saddle-belt monitoring valve device is provided, wherein the monitoring terminal device is an intelligent mobile device or a drone.

An embodiment of the present invention provides a saddle-belt monitoring valve device, wherein the information sending unit wirelessly sends the pipeline monitoring information through Bluetooth wireless transmission.

Through the technical means used in this creation, the saddle-belt monitoring valve device can perform wireless return of information in a way that reduces shielding from the ground through the ground exposed part of the battery accommodating box, so there is no need for additional information on the ground. To set up a communication station, there is no need to set up a signal line extending to the ground, which is easier to set up and does not occupy the floor space. Furthermore, through the design of the extension height of the box extending to the exposed part of the ground, the battery accommodating box has a large enough battery accommodating space to accommodate batteries with larger capacity and longer life, which can maintain the saddle belt monitoring. The long-term operation of the valve device does not require additional power supply equipment on the ground, nor does it need to replace the battery frequently. In addition, by integrating with the saddle-belt water diverter, the saddle-belt monitoring valve device can be installed on the fluid conveying pipe without the need to cut off the pipe or water, which further reduces the difficulty of construction and facilitates a large number of installations.

Embodiments of the present invention will be described below with reference to FIGS. 1 to 5 . This description is not intended to limit the implementation of the present creation, but is one of the embodiments of the present creation.

As shown in FIGS. 1 to 3, a saddle-belt monitoring plug valve device 100 according to an embodiment of the present invention is used to monitor a fluid delivery pipe F under the ground G, the saddle-belt monitoring plug The valve device 100 includes a saddle belt 1 , a water diverter 2 , a battery accommodating box 3 and a pipeline monitoring component 4 .

As shown in Fig. 1 and Fig. 2, the saddle belt 1 includes an upper saddle belt 11 and a lower saddle belt 12, the upper saddle belt 11 and the lower saddle belt 12 are abutted up and down to surround and fix the fluid conveying pipe F Between the upper saddle belt 11 and the lower saddle belt 12 , a plug valve communication hole 111 is formed through the upper saddle belt 11 . .

Specifically, in this embodiment, the upper saddle belt 11 and the lower saddle belt 12 are locked with each other by means of bolts 13 , and a tube is enclosed between the upper saddle belt 11 and the lower saddle belt 12 The road passes through the space 10 . The pipeline insertion space 10 is used for the fluid conveying pipe F to pass through, and the upper saddle belt 11 and the lower saddle belt 12 respectively clamp the fluid conveying pipe from top to bottom by the locking of the bolts 13 F. The pipeline insertion space 10 is generally a cylindrical space with a diameter of about 50 mm, preferably, a cylindrical space with a diameter of about 100 mm in this embodiment.

As shown in FIG. 1 and FIG. 2 , the water diverting plug 2 includes a water dividing plug body 21 , a communicating pipe part 22 and a dividing pipe part 23 , the water dividing plug body 21 has a top opening 211 , and the communicating pipe part 21 The pipe portion 22 and the shunt pipe portion 23 respectively extend from the shunt body 21 and communicate with the top opening 211 . The shunt 2 is disposed on the saddle 1 so that the shunt 21 passes through the communication pipe. The part 22 , the valve communication hole 111 and the pipe wall opening F1 communicate with the fluid delivery pipe F.

Specifically, the diverter valve is usually a valve valve used when installing a new branch pipeline on an existing pipeline. In the water diverter 2, the communication pipe portion 22 and the diversion pipe portion 23 are communicated with each other through the water diverter body 21. The switching of the water diversion adjustment position of the valve body 24 opens or closes the communication between the communication pipe part 22 and the diversion pipe part 23 . The water diversion plug 2 is provided with the saddle belt 1 so that the communication pipe portion 22 is engaged with the plug valve communication hole 111 of the upper saddle belt 11 so as to be connected to the fluid conveying pipe F through the plug valve communication hole 111 . The branch pipe part 23 is used for connecting branch pipes (not shown). Thereby, a part of the fluid in the fluid conveying pipe F can be diverted to the branch pipeline through the communication pipe part 22 , the water diverting plug body 21 , and the diverting pipe part 23 in sequence.

In addition, when installing the water diverter plug 2 and the saddle belt 1 to the fluid conveying pipe F, usually the water dividing plug 2 can be fixed to the fluid conveying pipe F by the saddle belt 1 first, and then use drilling A tool (not shown) passes through the top opening 211 of the water diversion plug body 21 , the valve body 24 , the communication pipe portion 22 , and the plug valve communication hole 111 of the upper saddle belt 11 to the fluid delivery pipe F. The pipe wall is provided with the pipe wall opening F1, so that the water diversion plug 2 is communicated with the fluid conveying pipe F. As shown in FIG. As mentioned above, in the installation operation of the water diverter 2 and the saddle belt 1, it is not necessary to cut off the pipe, and because of the communication between the water diverter 2 and the fluid conveying pipe F, the hole F1 can pass through the pipe wall. The fluid flowing into the water diversion valve 2 can also be closed in time by switching the water diversion adjustment position of the valve body 24 , without causing a large amount of fluid leakage, so there is no need to stop water during installation.

As shown in FIG. 1 and FIG. 2 , the bottom of the battery accommodating box 3 has a bolt assembly portion 31 , the top of the battery accommodating box 3 has a ground exposed portion 32 , and the battery accommodating box A battery accommodating space 30 is formed between the bolt assembly portion 31 and the ground exposed portion 32 of the body 3 by a predetermined box body extension height H, and the box body extension height H is set so that the battery body can accommodate the battery. The box body 3 is arranged on the water diverter 2 in such a way that the plug body assembling portion 31 is assembled and communicated with the top opening 211 of the water diverter plug body 21 and the ground exposed portion 32 is exposed to the ground G for signals. .

Specifically, the battery accommodating box 3 is arranged and combined with the water diverter 2 . In this embodiment, the bolt body assembly portion 31 is a threaded connection portion, and the battery accommodating box is formed by screwing the threaded connection portion to the threaded structure on the outer periphery of the top opening 211 of the water diverting plug body 21 . The body 3 is assembled and fixed on the top of the water diversion plug body 21 , and communicated with the water diversion plug body 21 through the plug body assembly portion 31 and the top opening 211 .

The ground-exposed portion 32 is disposed in such a manner that the signal is exposed to the ground G, wherein “signal exposure to the ground” refers to a configuration in which the signal can pass through the ground-exposed portion 32 and be directly transmitted (exposed) to the ground G, There may be various situations, including: the ground exposed portion 32 protrudes above the ground G; the top surface of the ground exposed portion 32 is the same height as the ground G; the ground exposed portion 32 is located below the ground G and is on the ground There is no signal shield between the exposed portion 32 and the ground G. For example: the ground exposed part 32 is located below the ventilation hole of the manhole cover of the ground G, because the signal can pass through the ground exposed part 32 and be directly transmitted (exposed) to the ground G through the ventilation hole of the manhole cover Therefore, this configuration belongs to the setting mode in which the signal is exposed to the ground G. In addition, of course, in order to enable the signal to be transmitted through the ground exposed portion 32 , the ground exposed portion 32 itself is preferably made of a material that does not affect signal transmission, such as plastic. In addition, as shown in FIG. 2 , the ground exposed portion 32 can be configured as a pavement cat-eye device or integrated with other pavement markings, whereby the ground exposed portion 32 not only does not interfere with the existing road, but can also be used as a road surface logo usage.

The battery accommodating box 3 has a predetermined extension height H of the box, and the box extension height H makes the battery accommodating box 3 extend from the top of the water diverter body 21 to the extent that the ground exposed portion 32 is in the Ground G exposed. The fluid conveying pipe F usually has a certain embedded depth limit, for example: more than 120 cm, so the extension height H of the box also has a corresponding size, so that the battery accommodating space formed by the battery accommodating box 3 The 30 is sized enough to hold a high-capacity, long-lasting battery.

As shown in FIGS. 1 to 3 , the pipeline monitoring assembly 4 includes a battery 41 , a control circuit module 42 , and at least one sensor 43 . The battery 41 is accommodated in the battery accommodating space 30 . , the control circuit module 42 is coupled to the battery 41 , and at least one of the sensors 43 is coupled to the control circuit module 42 through the plug assembly portion 31 , the top opening 211 , and the water diverter plug 21. The communication pipe portion 22, the valve communication hole 111 and the pipe wall opening F1 extend into the fluid conveying pipe F to sense and obtain the pipeline monitoring information I about the fluid conveying pipe F, the pipeline The monitoring information I at least includes fluid pressure information in the pipe, wherein the control circuit module 42 has an information sending unit 421, and the information sending unit 421 is configured to pass the pipeline monitoring information I through the battery accommodating box 3 The ground-exposed portion 32 is directly wirelessly transmitted to a monitoring terminal device 5 located on the ground G in such a manner that the ground-exposed portion 32 is less shielded by the ground.

Specifically, the battery 41 is used to supply the power required for the overall operation of the saddle-belt monitoring valve device 100 , including: the wireless transmission of signals by the control circuit module 42 and the wireless transmission of at least one sensor 43 . information sensing. Since the battery accommodating space 30 formed by the battery accommodating box 3 has a sufficient size, a large capacity and long-lasting battery can be selected for the battery 41 to maintain the long-term operation of the saddle-belt monitoring valve device 100 Operation, for example: continuous power supply for 3 years. Therefore, there is no need to set up a power supply device on the ground G, and there is no need to replace the battery 41 frequently.

The control circuit module 42 is used to control the overall operation of the saddle-belt monitoring valve device 100 . In this embodiment, the control circuit module 42 and the battery 41 are disposed in the battery accommodating space 30 and above the battery 41 , but the invention is not limited to this. In other embodiments, the control circuit module 42 can be disposed below or on one side of the battery 41 , or the control circuit module 42 can be disposed outside the battery accommodating space 30 , for example: disposed in the battery The inner wall of the accommodating box 3 is either in the bolt assembly portion 31 or the ground exposed portion 32 . In other words, the control circuit module 42 can be set arbitrarily, as long as the pipeline monitoring information I wirelessly sent by the information sending unit 421 can be transmitted to the monitoring terminal device 5 through the ground exposed portion 32 . In this embodiment, the information sending unit 421 wirelessly sends the pipeline monitoring information I through Bluetooth wireless transmission, and the transmission distance can reach about 30-100 meters. Of course, the present invention is not limited to this, and other wireless transmission methods can also be applied to the information sending unit 421 . In addition, the monitoring terminal device 5 can be an intelligent mobile device or a drone. The monitoring personnel can use the smart mobile device to receive the pipeline monitoring information I, and can also use the drone to receive the pipeline monitoring information I remotely.

In this embodiment, the pipeline monitoring component 4 includes a plurality of the sensors 43. In addition to the fluid pressure information in the pipeline, the pipeline monitoring information I sensed by the plurality of sensors 43 can also be It includes one or more information among toxic substance detection information, fluid turbidity information in the pipe, pH information of the fluid in the pipe, plastic particle content information in the fluid in the pipe, and fluid flow information in the pipe. As the name implies, the pressure information of the fluid in the pipe is information about the fluid pressure in the pipe of the fluid conveying pipe F, and the toxic substance detection information is information about the content of toxic substances in the fluid in the pipe of the fluid conveying pipe F. The turbidity information is information about the water turbidity of the fluid in the pipe of the fluid conveying pipe F, and the pH information of the fluid in the pipe is information about the pH value (pH value) of the fluid in the pipe of the fluid conveying pipe F. The content information of the fluid plastic particles is information about the content of plastic particles in the fluid in the pipe of the fluid conveying pipe F, and the fluid flow information in the pipe is information about the flow rate of the fluid in the pipe of the fluid conveying pipe F. FIG. Corresponding to the different pipeline monitoring information I, the types of the sensors 43 used are also different, and the sensors 43 all extend from the battery accommodating box 3 through the water diverter 2 into the Sensing is performed directly in the fluid delivery pipe F to obtain accurate monitoring information I of the pipe.

As shown in FIGS. 1 to 3 , according to the saddle-belt monitoring valve device 100 according to an embodiment of the present invention, the water diverter 2 further includes an electric valve body driver 25 coupled to the battery 41 and the The control circuit module 42, the control circuit module 42 has a signal receiving unit 422, and the signal receiving unit 422 is configured to reduce the ground shielding through the ground exposed portion 32 of the battery accommodating box 3 Receiving a valve body control signal from the ground G, the control circuit module 42 controls the electric valve body driver 25 according to the valve body control signal, and drives the water diverter body 21 through the electric valve body driver 25 The valve body 24 in the middle of the valve body 24 to change the water separation adjustment position of the valve body 24 .

Specifically, since the saddle-belt monitoring valve device 100 of the present invention can use the battery 41 with a large capacity and a long life, and the pipeline monitoring component 4 including the battery 41 is integrated into the water diverter 2 , Therefore, in addition to information sensing and signal transmission, there is still enough power to adjust the valve body 24 in an electric manner nearby.

As shown in FIG. 4 , according to the saddle-belt monitoring valve device 100 according to an embodiment of the present invention, the battery 41 is a rechargeable battery, the control circuit module 42 has a wireless charging unit 423 , and the wireless charging unit 423 is configured to be inductively coupled to a wireless charging device 6 above the ground G in a manner of reducing shielding by the ground through the ground exposed portion 32 of the battery accommodating box 3 to charge the rechargeable battery.

As shown in FIG. 3 and FIG. 5, according to the saddle-belt monitoring plug valve device 100 according to an embodiment of the present invention, the pipeline monitoring information I includes pipeline leakage point information, and at least one of the sensors 43 further includes A pipeline leak point detector, which is sent by a detection signal transmission unit 432 of another saddle belt monitoring plug valve device 100' with a detection signal receiving unit 431 through the fluid conveying A leak detection signal of the pipe is obtained, and the information of the leak point of the pipe is obtained by sensing. Specifically, with a large number of installations of the saddle-belt monitoring valve device 100 , in addition to monitoring local areas to determine whether the fluid conveying pipe F leaks, various methods such as ultrasonic detection can be used. Furthermore, the specific position of the leakage point F2 in the entire pipeline section between the two adjacent saddle-belt-type monitoring plug valve devices 100 and 100' is further accurately detected.

With the above-mentioned structure, the saddle-belt monitoring valve device 100 of the present invention can perform wireless return of information in a manner that reduces shielding by the ground through the ground-exposed portion 32 of the battery accommodating box 3 , and thus does not need to be used. A separate communication station is set up on the ground, and there is no need to set up a signal line extending to the ground, which is easier to set up and does not occupy the ground space. Furthermore, through the design of the extension height H of the box extending to the ground exposed portion 32 , the battery accommodating box 3 has a battery accommodating space 30 large enough to accommodate batteries with larger capacity and longer life. , it can maintain the long-term operation of the saddle-belt-type monitoring valve device 100 , and it is not necessary to set up additional power supply equipment on the ground, and it is not necessary to frequently replace the battery. In addition, by being integrated with the saddle-belt water diverter, the saddle-belt monitoring valve device 100 can be installed on the fluid conveying pipe F without the need to cut off the pipe or water, which further reduces the difficulty of construction and is convenient for a large number of installations .

The above descriptions and descriptions are only the descriptions of the preferred embodiments of the present invention. Those with ordinary knowledge in this technology can make other modifications according to the scope of the patent application defined below and the above descriptions, but these modifications should still be It is the creative spirit of this creation and within the scope of rights of this creation.

100: Saddle belt monitoring plug valve device 100': Saddle Belt Monitoring Plug Valve Device 1: saddle belt 10: Pipeline penetration space 11: Upper saddle belt 111: Plug valve connecting hole 12: Lower saddle belt 13: Bolts 2: water hydrant 21: Water-separating plug 211: top opening 22: Connecting pipe part 23: shunt pipe 24: valve body 25: Electric valve body driver 3: Battery storage box 30: Battery storage space 31: Bolt body assembly 32: Ground exposed part 4: Pipeline monitoring components 41: Battery 42: Control circuit module 421: Information sending unit 422: Signal receiving unit 423: Wireless Charging Unit 43: Sensor 431: Detection signal receiving unit 432: Detection signal sending unit 5: Monitoring terminal device 6: Wireless charging device F: Fluid delivery tube F1: Pipe wall opening F2: leak point G: ground H: Box extension height I: Pipeline monitoring information

[Fig. 1] is a schematic diagram showing a saddle-belt monitoring plug valve device according to an embodiment of the present invention; [Fig. 2] is a schematic cross-sectional view showing the saddle-belt monitoring plug valve device according to the embodiment of the present invention when it is installed in a fluid delivery pipe; [Fig. 3] is a block diagram showing the saddle-belt monitoring plug valve device according to the embodiment of the present invention when sending pipeline monitoring information; [Fig. 4] is a block diagram showing the saddle-belt monitoring plug valve device according to an embodiment of the present invention when wireless charging is performed; [FIG. 5] is a schematic diagram showing a saddle-belt monitoring plug valve device according to an embodiment of the present invention when a leak point is detected.

100: Saddle belt monitoring plug valve device

1: saddle belt

11: Upper saddle belt

111: Plug valve connecting hole

12: Lower saddle belt

2: water hydrant

21: Water-separating plug

211: top opening

22: Connecting pipe part

23: shunt pipe

24: valve body

25: Electric valve body driver

3: Battery storage box

30: Battery storage space

31: Bolt body assembly

32: Ground exposed part

4: Pipeline monitoring components

41: Battery

42: Control circuit module

43: Sensor

F: Fluid delivery tube

F1: Pipe wall opening

G: ground

H: Box extension height

Claims (8)

A saddle-belt monitoring plug valve device for monitoring a fluid delivery pipe located under the ground, the saddle-belt monitoring plug valve device comprising: a saddle belt, including an upper saddle belt and a lower saddle belt, the upper saddle belt and the lower saddle belt are abutted up and down to surround and fix the fluid conveying pipe between the upper saddle belt and the lower saddle belt, the upper saddle belt A plug valve communication hole is formed through the belt, and the plug valve communication hole is provided with an opening corresponding to a pipe wall of the fluid conveying pipe; A water diversion hydrant includes a water diversion plug body, a communication pipe part and a diversion tube part, the water diversion plug body has a top opening, the communication tube part and the diversion tube part respectively extend from the water diversion plug body and communicated with the top opening, the water diversion plug is arranged on the saddle belt so that the water diversion plug body is communicated with the fluid conveying pipe through the communication pipe portion, the plug valve communication hole and the pipe wall opening; and A battery accommodating box, the bottom of the battery accommodating box has a bolt assembly portion, the top of the battery accommodating box has a ground exposed portion, and the bolt assembling portion of the battery accommodating box A battery accommodating space is formed by a predetermined extension height of the box from the ground exposed portion, and the extension height of the box is set so that the battery accommodating box is assembled and communicated with the bolt assembly portion The top opening of the water dividing plug body and the ground-exposed portion are disposed on the water dividing plug in such a manner that the signal is exposed to the ground; and A pipeline monitoring component includes a battery, a control circuit module, and at least one sensor, the battery is accommodated in the battery accommodating space, the control circuit module is coupled to the battery, at least one sensor The measuring device is coupled to the control circuit module and extends into the fluid through the plug body assembly part, the top opening, the water diversion plug body, the communication pipe part, the plug valve communication hole and the pipe wall opening The delivery pipe is used to sense and obtain pipeline monitoring information about the fluid delivery pipe, the pipeline monitoring information at least includes fluid pressure information in the pipe, wherein the control circuit module has an information sending unit, and the information sending unit is configured The pipeline monitoring information is directly wirelessly transmitted to a monitoring terminal device located on the ground in a manner of reducing the ground shielding through the ground exposed portion of the battery accommodating box. The saddle-belt monitoring valve device according to claim 1, wherein the water diverter further comprises an electric valve body driver coupled to the battery and the control circuit module, and the control circuit module has a signal receiving unit , the signal receiving unit is configured to receive a valve body control signal from above the ground in a way that the ground exposed portion of the battery accommodating box is less shielded from the ground, and the control circuit module is based on the valve The body control signal controls the electric valve body driver, and the electric valve body driver drives a valve body in the water separation plug body to change the water separation adjustment position of the valve body. The saddle-belt monitoring plug valve device of claim 1, wherein the pipeline monitoring component includes a plurality of the sensors, and the pipeline monitoring information sensed by the plurality of the sensors further includes toxic substance detection information , one or more information among the turbidity information of the fluid in the pipe, the pH information of the fluid in the pipe, the content information of the plastic particles in the fluid in the pipe, and the flow information of the fluid in the pipe. The saddle-belt monitoring plug valve device as claimed in claim 1, wherein the ground-exposed portion is configured as a pavement cat-eye device. The saddle-belt monitoring valve device of claim 1, wherein the battery is a rechargeable battery, the control circuit module has a wireless charging unit, and the wireless charging unit is configured to pass through the battery accommodating box The ground-exposed portion of the body is inductively coupled to a wireless charging device on the ground in a manner of reducing shielding by the ground, so as to charge the rechargeable battery. The saddle-belt monitoring plug valve device according to claim 1, wherein the pipeline monitoring information includes pipeline leakage point information, and at least one of the sensors further includes a pipeline leakage point detector, the pipeline leakage point detecting The device senses and obtains the leakage point information of the pipeline by receiving a detection signal sending unit of another saddle-belt monitoring valve device with a detection signal receiving unit to send a leak detection signal through the fluid conveying pipe. The saddle-belt monitoring valve device according to claim 1, wherein the monitoring terminal device is an intelligent mobile device or a drone. The saddle-belt monitoring valve device of claim 1, wherein the information sending unit wirelessly sends the pipeline monitoring information through Bluetooth wireless transmission.

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