KR102557255B1 - Remotely water meter terminal - Google Patents

Abstract

The present invention relates to a remote water meter reading terminal, and more particularly, to a self-powered remote water meter reading terminal mounted on a water pipe, capable of remotely transmitting data of a water pipe flowmeter to the outside, and operating through self-power generation.
The self-powered remote water meter reading terminal of the present invention includes a hollow pipe connected to a water pipe; a body mounted outside the pipe; an input unit mounted on the main body to receive data of the water pipe flowmeter; a transmitter mounted on the main body and transmitting the data received through the input unit to a server; a battery mounted inside the main body; A self-power generation module coupled to the pipe and generating electricity by a fluid flowing inside the pipe; wherein the electricity generated in the self-power generation module is charged in the battery and then supplies electricity to the input unit and the transmitter. It is characterized in that it is supplied and operated.

Description

Self-powered remote water meter reading terminal { Remotely water meter terminal }

The present invention relates to a remote water meter reading terminal, and more particularly, to a self-powered remote water meter reading terminal mounted on a water pipe, capable of remotely transmitting data of a water pipe flowmeter to the outside, and operating through self-power generation.

In general, tap water is treated at a water purification plant and then supplied through a large pipe in each district in the case of a city, and in each district, tap water is supplied by being classified into medium blocks and small blocks.

In addition, in general household housing and commercial building densely populated areas, tap water is supplied to end users by connecting large pipes buried under roads to small pipes.

At this time, when a small pipe is called a 'branch line', most of the water leakage occurs in the branch line, and this branch line is connected from the outdoors to the indoor and is divided into indoor and outdoor based on the water meter.

By the way, it is a rule that the water supply company (local government in Korea) manages the outdoor water pipe, and the user (landlord) manages the indoor water pipe.

Therefore, when water leakage occurs outdoors, a loss occurs to the water service provider, and when water leakage occurs indoors, a user (landlord) suffers a large amount of water charges.

To this end, various types of conventional technologies for detecting water leakage by installing a water leakage detection device in a water pipe have been proposed and applied.

In order to meter the water consumption, if a meter reader visits the consumer and reads the instructions displayed on the meter, the labor cost of the meter reader increases, and there are many problems with the difficulty of meter reading due to the absence of the consumer and many false meter readings. , Recently, a method of remotely and automatically reading water usage is preferred.

For remote meter reading as described above, a remote water meter reading terminal should be installed on a water pipe or the like.

However, the conventional remote water meter reading terminal has the following problems and disadvantages.

After the remote water meter reading terminal was installed in the water pipe, the administrator had to visit and visually check whether the meter reading terminal was properly installed in the water pipe, and in case of theft, it was impossible to quickly determine whether the meter was stolen.

In addition, it was difficult to easily install the remote water meter reading terminal in the water pipe, and there was a high risk of theft.

In addition, conventionally, since electricity used in the remote water meter reading terminal is supplied through a battery, there is a problem in that the meter reading terminal cannot be used when the battery is discharged.

Registered Patent No. 10-1489921 Patent Publication 10-2015-0138010 Registered Patent No. 10-1627793

The present invention is intended to solve the above-described problems, and after installing a remote water meter reading terminal in a water pipe, an administrator can easily determine whether the meter reading terminal is installed in the water pipe without directly visiting and visually checking whether the meter reading terminal is installed in the water pipe. In the case of theft, the purpose is to provide a remote water meter reading terminal that enables quick identification of theft.

Further, the present invention is to solve the above problems, and an object of the present invention is to provide a remote water meter reading terminal that can be easily installed in a water pipe and can prevent theft.

In addition, the present invention is to solve the above problems, and an object of the present invention is to provide a remote water meter reading terminal that can be used for a long time without a battery problem by generating electricity through self-generation.

In order to achieve the above object, a self-powered remote water meter reading terminal of the present invention includes a hollow pipe connected to a water pipe; a body mounted outside the pipe; an input unit mounted on the main body to receive data of the water pipe flowmeter; a transmitter mounted on the main body and transmitting the data received through the input unit to a server; a battery mounted inside the main body; A self-power generation module coupled to the pipe and generating electricity by a fluid flowing inside the pipe; wherein the electricity generated in the self-power generation module is charged in the battery and then supplies electricity to the input unit and the transmitter. It is characterized in that it is supplied and operated.

The self-powered module includes a vertical support disposed inside the pipe; a horizontal support connected in a horizontal direction from the vertical support; a blade rotatably coupled to an end of the horizontal support and rotated by the fluid flowing inside the pipe; a generator mounted outside the pipe and connected to the battery; a first rotating shaft mounted inside the vertical support and having an end disposed inside the generator; a second rotating shaft mounted inside the horizontal support and rotating together with the rotation of the blade; and a bevel gear unit connecting the first rotation shaft and the second rotation shaft, wherein when the second rotation shaft is rotated by the blade, the first rotation shaft operates the generator while rotating by the bevel gear unit. to generate electricity.

Alternatively, the self-powered module includes a vertical support disposed inside the pipe; a third rotating shaft that is connected in the horizontal direction from the vertical support and rotates; a blade coupled to an end of the third rotating shaft, rotating together with the third rotating shaft, and rotating by the fluid flowing inside the pipe; a magnet coupled to the third rotating shaft; and a coil part having a ring shape disposed outside the magnet and connected to the battery, wherein the magnet rotates along with the third rotation shaft when the blade rotates the third rotation shaft. Electricity is generated in the coil part disposed outside.

The coil part is coupled to and supported by the vertical support in a sealed state, an inner circumferential surface of the coil part is spaced apart from the magnet, and an outer circumferential surface of the coil part is spaced apart from the inner circumferential surface of the pipe.

Alternatively, the self-powered module includes a vertical support disposed inside the pipe; a third rotating shaft that is connected in the horizontal direction from the vertical support and rotates; a blade coupled to an end of the third rotating shaft, rotating together with the third rotating shaft, and rotating by the fluid flowing inside the pipe; a magnet coupled to an end of the blade; A ring-shaped coil part disposed outside the magnet and connected to the battery, wherein when the blade rotates, the magnet rotates together and electricity is generated in the coil part disposed outside the magnet. do.

When the magnet rotates, heat is generated in the coil unit to heat the fluid flowing inside the pipe.

a rotation sensor for detecting rotation of the blade; Further comprising a control unit for controlling the input unit and the transmitter, and when the rotation of the blade is detected by the rotation sensor but the battery is not charged, the control unit transmits an error message of the self-power generation module through the transmitter. Send a signal to the server.

According to the remote water meter reading terminal of the present invention as described above, the following effects are obtained.

According to the present invention, when the water meter reading terminal is installed in the water pipe, it is automatically operated, and in the event of theft, etc., it is possible to immediately identify and take action.

In particular, after the remote water meter reading terminal is installed in the water pipe, the administrator can easily determine whether the meter reading terminal is installed in the water pipe through the connection detection sensor without having to visit the water pipe and check with the naked eye.

In addition, by installing the earthquake detection sensor, it is possible to sense in advance an earthquake transmitted through the water pipe, etc., and by mounting the humidity sensor, it is possible to prevent malfunction or breakdown of the water meter reading terminal due to moisture introduced into the main body. You can anticipate and take action.

In addition, the present invention can easily fasten the main body to the water pipe by the fastening member, and can prevent the water meter reading terminal from being separated from the water pipe or stolen by the fixing member coupled to the fastening member. .

In addition, the present invention generates electricity through self-generation, so that the meter reading terminal can be used for a long time without a battery problem.

1 is a cross-sectional view of a state in which a remote water meter reading terminal according to a first embodiment of the present invention is mounted on a water pipe;
2 is a cross-sectional structure diagram of a remote water meter reading terminal according to a second embodiment of the present invention;
3 is a cross-sectional view of a state in which the remote water meter reading terminal of FIG. 2 is mounted on a water pipe;
4 is a cross-sectional structure diagram of a remote water meter reading terminal according to a modified second embodiment of the present invention;
5 is a cross-sectional structure diagram of a remote water meter reading terminal according to a third embodiment of the present invention;
6 is a cross-sectional view of a state in which the remote water meter reading terminal of FIG. 5 is mounted on a water pipe;
7 is a side structure diagram of a remote water meter reading terminal according to a fourth embodiment of the present invention;
8 is a side structure diagram of a remote water meter reading terminal according to a fifth embodiment of the present invention;
9 is a side structural diagram of a remote water meter reading terminal according to a sixth embodiment of the present invention;

Example 1

The remote water meter reading terminal of the present invention includes a main body 10, an input unit 11, a transmitter 12, a battery 13, a fastening member 20, a fastening detection sensor 30, a controller ( 40) is included.

The body 10 is mounted on the water pipe 1.

The main body 10 is sealed so that the inside and outside are blocked.

The input unit 11 is mounted inside the main body 10 and receives data of the water pipe 1 flowmeter.

The transmitting unit is mounted inside the main body 10 and wirelessly transmits the data received through the input unit 11 to the server.

The battery 13 is mounted inside the main body 10 and supplies power to the input unit 11 and the transmission unit.

The fastening member 20 couples the main body 10 to the water pipe 1 .

The fastening detection sensor 30 is coupled to the main body 10 and detects whether the fastening member 20 is coupled to the water pipe 1 .

The controller 40 controls the input unit 11 and the transmitter 12 .

When the coupling detection sensor 30 detects that the coupling member 20 is coupled to the water pipe 1, the control unit 40 operates the input unit 11 and the transmitter 12.

Therefore, it is possible to prevent the battery 13 from being consumed unnecessarily when the water meter reading terminal of the present invention is not mounted on the water pipe 1, and the main body 10 is connected to the main body 10 through the fastening member 20. When fastened to the water pipe 1, the water meter reading terminal is automatically operated by the fastening detection sensor 30 and the control unit 40, so it is convenient to use.

And, when the fastening sensor 30 detects that the fastening member 20 is separated from the water pipe 1 while the input unit 11 and the transmitter 12 are operating, the controller 40 controls the The theft signal is sent to the server through the transmitter 12.

Through this, in a state where the water meter reading terminal of the present invention is fastened to the water pipe 1, a manager can quickly and easily determine whether or not it has been stolen.

The fastening detection sensor 30 may be formed in various shapes and structures.

In this embodiment, the fastening detection sensor 30 protrudes from the main body 10 toward the water pipe 1 .

When the fastening member 20 is coupled to the water pipe 1, the fastening detection sensor 30 is turned on while in contact with the water pipe 1, and detects that the fastening member 20 is coupled to the water pipe 1. .

In addition, when the fastening sensor 30 is suddenly turned OFF from the ON state, the control unit 40 determines that the fastening member 20 is separated from the water pipe 1, and transmits the signal through the transmitter 12. A theft signal of the water meter reading terminal is sent to the server.

The present invention may further include an earthquake detection sensor 14 and a humidity sensor 15.

The earthquake detection sensor 14 is mounted on the main body 10 .

When the coupling detection sensor 30 detects that the coupling member 20 is coupled to the water pipe 1, the controller 40 operates the earthquake detection sensor 14.

The earthquake detection sensor 14 detects vibration transmitted through the water pipe 1 and transmits related information to the server through the transmitter 12 when an earthquake is detected, so that the manager detects and detects the earthquake in advance. can be dealt with.

The humidity sensor 15 is mounted inside the main body 10 to measure the humidity inside the main body 10 .

The inside and outside of the body 10 are sealed, so that, in principle, moisture from the outside should not flow into the inside.

However, for various reasons, moisture or the like may flow into the main body 10. If this is prevented as it is, the input unit disposed inside the main body 10 may be caused by moisture that has flowed into the main body 10. There is a high possibility that various electrical and electronic components such as (11) and the transmitter 12 may fail or malfunction.

In the present invention, the humidity sensor 15 is mounted inside the main body 10, and when the measured value measured by the humidity sensor 15 exceeds a preset reference value, the control unit 40 controls the main body 10 to transmit a signal indicating excessive moisture in the inside to the server through the transmitter 12.

Through this, the administrator can easily determine whether moisture has flowed into the main body 10, and if moisture has flowed into the main body 10 in excess of a reference value, the water meter reading terminal of the present invention may malfunction or fail. You can take precautionary measures to prevent it from happening.

The fastening member 20 is composed of a coupling surface portion 21 and a close contact portion 22 .

The coupling surface portion 21 is coupled to one surface of the main body 10 .

The contact portion 22 is made of a pair and protrudes toward the water pipe 1 from both sides of the coupling surface portion 21 .

In a state in which the water pipe 1 is inserted and disposed between the coupling surface portion 21 and the close contact portion 22, the ends of the close contact portion 22 are fixedly coupled to each other by a fixing member 50 to form the fastening member (20) is prevented from being separated from the water pipe (1).

At this time, the fixing member 50 may be made of various fixing means such as wires, bolts and nuts.

In this embodiment, the coupling surface portion 21 and the close contact portion 22 are made of an integrated leaf spring.

A pair of contact parts 22 disposed facing each other are inclined in a direction facing each other.

When the water pipe 1 is inserted into the fastening member 20, the fastening member 20 made of a leaf spring is forcibly expanded.

When the water pipe 1 passes between a pair of mutually spaced contact parts 22, the contact part 22 is forcibly elastically deformed in a direction away from each other by the diameter of the water pipe 1, When the water pipe 1 is disposed inside the fastening member 20, the elastically deformed contact portion 22 is restored and brought into close contact with the outer circumferential surface of the water pipe 1.

Through this, the fastening member 20 can be brought into close contact with the water pipe 1 .

After that, by using the fixing member 50 to interconnect the ends of the contact parts 22 that are spaced apart from each other, the fastening member 20 is prevented from being separated from the water pipe 1.

As described above, in the present invention, when the water meter reading terminal is installed in the water pipe 1, it is automatically operated, and in case of theft, etc., it is possible to immediately identify and take action.

In particular, after the remote water meter reading terminal is installed in the water pipe 1, the administrator does not directly visit and visually check whether the meter reading terminal is installed in the water pipe 1 through the connection detection sensor 30. can be easily identified without

In addition, by mounting the earthquake detection sensor 14, it is possible to sense in advance an earthquake transmitted through the water pipe 1, etc., and by mounting the humidity sensor 15, the Measures can be taken by identifying in advance that the water meter reading terminal malfunctions or breaks down due to moisture.

In addition, the present invention can easily fasten the body 10 to the water pipe 1 by the fastening member 20, and the water supply by the fixing member 50 coupled to the fastening member 20 It is possible to prevent the meter reading terminal from being separated from the water pipe 1 or being stolen.

Example 2

The second embodiment has a difference in the fastening member 20 compared to the first embodiment, and this will be mainly described.

The fastening member 20 includes a coupling surface portion 21, a close contact portion 22, and a first wire 23.

The coupling surface portion 21 is coupled to one surface of the main body 10 .

The contact portion 22 is made of a pair and protrudes toward the water pipe 1 from both sides of the coupling surface portion 21 .

The pair of close contact parts 22 are rotatably coupled to both sides of the coupling surface part 21 .

The first wire 23 is made of a pair, and each end is coupled to the coupling surface portion 21 and each other end is coupled to the close contact portion 22, and the inside of the coupling surface portion 21 and the close contact. It is arranged inside the part 22.

In this structure, when the water pipe 1 is inserted and disposed inside the coupling surface portion 21 and the close contact portion 22, the first wire 23 located inside thereof is on the outer circumferential surface of the water pipe 1 It bends while contacting, so that the close contact part 22 is rotated in the direction of the water pipe 1 so that it adheres.

After that, the end of the close contact part 22 is fastened to each other with the fixing member 50 .

As described above, in the present embodiment, when the water pipe 1 is inserted and disposed inside the fastening member 20, the outer circumferential surface of the water pipe 1 while the contact portion 22 rotates by the first wire 23 Through this, the ends of the pair of close contact parts 22 in close contact with the outer circumferential surface of the water pipe 1 can be easily fastened with the fixing member 50.

At this time, the first wire 23 is made of a material having elasticity, and expands when the water pipe 1 is inserted into the fastening member 20, and the water pipe 1 is separated from the fastening member 20. When separated, the close contact part 22 can be automatically opened to its original position while being restored to its original state.

In addition, the pair of first wires 23 may be arranged to cross each other.

That is, the pair of first wires 23 have one end connected to the coupling surface portion 21 and the other end connected to the close contact portion 22 disposed far apart from each other so that intermediate portions of the pair of first wires 23 cross each other.

Due to this structure, when the water pipe 1 is inserted into the fastening member 20, the contact portion 22 can be more strongly adhered to the outer circumferential surface of the water pipe 1.

Since other matters are identical and similar to those of the first embodiment, a detailed description thereof will be omitted.

3rd embodiment

The third embodiment has a difference in the fastening member 20 compared to the first embodiment, and this will be mainly described.

The fastening member 20 includes a coupling surface portion 21, a contact portion 22, a rack gear 24, a pinion gear 25, a torsion spring 26, and a second wire 27. It is done by

The coupling surface portion 21 is coupled to one surface of the main body 10 .

The contact portion 22 is made of a pair and protrudes toward the water pipe 1 from both sides of the coupling surface portion 21 .

The pair of close contact parts 22 are rotatably coupled to both sides of the coupling surface part 21 .

The rack gear 24 penetrates the coupling surface portion 21 in the vertical direction and has gears formed on both sides.

The rack gear 24 is mounted to move vertically while penetrating the coupling surface 21 .

The pinion gear 25 is disposed on both sides of the rack gear 24, meshes with the rack gear 24, and is rotatably coupled to the coupling surface 21.

The torsion spring 26 is mounted on the rotating hinge point of the coupling surface portion 21 and the close contact portion 22 to apply force so that the close contact portion 22 rotates in the inward direction of the fastening member 20 do.

The second wire 27 has one end coupled to the pinion gear 25 and the other end coupled to the contact portion 22 .

At this time, one end of the second wire 27 is wound around the outer circumferential surface of the pinion gear 25.

When the water pipe 1 is inserted and disposed between the coupling surface portion 21 and the close contact portion 22, the rack gear 24 protruding downward is pushed up by the water pipe 1, As the rack gear 24 rises, the pinion gear 25 geared to both sides of the rack gear 24 rotates.

As the second wire 27 wound around the pinion gear 25 is loosened by the rotation of the pinion gear 25, the contact part 22 is connected to the water pipe by the elastic restoring force of the torsion spring 26 ( 1) to adhere to the outer circumferential surface of the water pipe (1).

In this embodiment, the fastening member 20 may be fixed to the water pipe 1 in the above state, or the fixing member 50 mentioned in the first embodiment may be additionally coupled and fixed.

Meanwhile, the coupling detection sensor 30 may detect whether or not the coupling member 20 is coupled to the water pipe 1 in various ways. In this embodiment, the coupling detection sensor 30 is the rack gear Whether or not the fastening member 20 is coupled to the water pipe 1 is detected by detecting whether or not 24 goes up and down.

Specifically, the fastening detection sensor 30 detects whether the rack gear 24 is raised or lowered.

When the rack gear 24 is pushed upward by the water pipe 1, the coupling detection sensor 30 detects that the coupling member 20 is coupled to the water pipe 1, and the rack gear 24 is When descending, the fastening detection sensor 30 detects that the fastening member 20 is separated from the water pipe 1 .

At this time, the fastening member 20 may further include a first spring 28 that pushes the rack gear 24 downward.

When the rack gear 24 ascends, the first spring 28 is compressed, and when the water pipe 1 is separated, the rack gear 24 automatically descends by the elastic restoring force of the first spring 28. will do

Through this, when the water pipe 1 is separated from the fastening member 20, the rack gear 24 is lowered by the first spring 28, so that the fastening sensor 30 detects the lowered rack. By sensing the gear 24, it is possible to detect when the fastening member 20 is separated from the water pipe 1.

In addition, by the descent of the rack gear 24 by the first spring 28, the pinion gear 25 winds the second wire 27 while rotating reversely, and thereby the second wire ( The contact part 22 connected to 27) rotates in an outward direction and unfolds to its original state.

Since other matters are identical and similar to those of the first embodiment, a detailed description thereof will be omitted.

Example 4

The remote water meter reading terminal of the fourth embodiment is of a self-powered type.

The remote water meter reading terminal of this embodiment includes a pipe 60, a body 10, an input unit 11, a transmitter 12, a battery 13, a self-powered module 70, and the like. .

The pipe 60 is made of a hollow shape connected to the water pipe 1.

The body 10 is mounted outside the pipe 60.

The main body 10 may be fixedly mounted on the outside of the pipe 60, and is coupled to the pipe 60 through the fastening member 20 of any one of the first to third embodiments described above. It could be.

At this time, the fastening detection sensor 30 may be mounted on the main body 10 .

The input unit 11 is mounted on the main body 10 and receives data from the water pipe 1 flowmeter.

The transmitter 12 is mounted on the main body 10 and transmits data received through the input unit 11 to a server.

The battery 13 is installed inside the main body 10 and supplies power to the input unit 11 and the transmitter 12 .

The self-power generation module 70 is coupled to the pipe 60 and generates electricity by a fluid (water) flowing inside the pipe 60 .

After the electricity generated in the self-powered module 70 is charged in the battery 13, electricity is supplied to the input unit 11 and the transmitter 12 to operate.

The self-powered module 70 includes a vertical support 71, a horizontal support 72, a blade 73, a generator 74, a first rotational shaft 75, a second rotational shaft 76, , It includes a bevel gear portion 77.

The vertical support 71 is disposed inside the pipe 60 in a vertical direction.

The horizontal support 72 is connected to the vertical support 71 in the horizontal direction.

The blade 73 is rotatably coupled to the end of the horizontal support 72 and rotates by the fluid flowing inside the pipe 60 .

The generator 74 is mounted outside the pipe 60 and is connected to the battery 13 .

The first rotating shaft 75 is mounted inside the vertical support 71, and the end is disposed inside the generator 74.

The second rotary shaft 76 is mounted inside the horizontal support 72 and rotates together with the rotation of the blade 73 .

The bevel gear unit 77 connects the first rotational shaft 75 and the second rotational shaft 76 so that the rotational force of the second rotational shaft 76 is transmitted to the first rotational shaft 75, The rotating shaft 75 is allowed to rotate.

With this structure, when the second rotation shaft 76 is rotated by the blade 73, the first rotation shaft 75 rotates by the bevel gear part 77 and operates the generator 74 to generate electricity. is generated, and the electricity generated by the generator 74 is charged in the battery 13.

Meanwhile, the present embodiment may further include a rotation sensor 80 and a control unit 40.

The rotation sensor 80 detects rotation of the blade 73 .

The controller 40 controls the input unit 11 and the transmitter 12 .

When the rotation of the blade 73 is detected by the rotation sensor 80 but the battery 13 is not charged, the control unit 40 operates the self-power generation module 70 through the transmitter 12. An error signal of is transmitted to the server.

Through this, even if the blade 73 is rotated, the battery 13 is not charged, that is, the self-power generation module 70 notifies the manager that an error has occurred, so that the manager can ) can be quickly checked.

In addition, the blade 73 is made of a structure that can be folded to the rear where the fluid flows according to the flow rate, so that when the user wants to use a lot of water, the blade 73 is partially folded by the strong flow rate and the water It can also be made to flow better without the obstruction of the blades 73.

At this time, the blade 73 is hinged to the second rotation shaft 76 so as to be folded backward, and a torsion spring 26 or the like is mounted between the blade 73 and the second rotation shaft 76, When the external force is small, the blade 73 maintains a deployed state by the elastic restoring force of the torsion spring 26, and when the external force increases due to the flow rate, the blade 73 compresses the torsion spring 26 and is partially folded. make it possible

Since the other matters are the same or similar to those of the first to third embodiments, or a configuration suitable for them is adopted, a detailed description thereof will be omitted.

Example 5

The fifth embodiment has a difference in the configuration and structure of the self-power generation module 70 compared to the fourth embodiment, and this will be mainly described.

The self-powered module 70 includes a vertical support 71, a third rotary shaft 78, a blade 73, a magnet 79a, and a coil unit 79b.

The vertical support 71 is disposed inside the pipe 60 in a vertical direction.

The third rotating shaft 78 is connected to the vertical support 71 in the horizontal direction and rotates.

The blade 73 is coupled to the end of the third rotation shaft 78 and rotates together with the third rotation shaft 78, and is rotated by the fluid flowing inside the pipe 60.

The magnet 79a is coupled to the circumference of the third rotating shaft 78 that rotates.

Therefore, when the third rotating shaft 78 rotates, the magnet 79a rotates together.

The coil part 79b has a ring shape, is disposed outside the magnet 79a, and is connected to the battery 13.

When the third rotational shaft 78 is rotated by the blade 73, the magnet 79a rotates together with the third rotational shaft 78 and the coil part 79b disposed outside the magnet 79a electricity is generated in

The coil part 79b may be coupled to the inner circumferential surface of the pipe 60, but preferably, as shown in the drawing of the present embodiment, the coil part 79b is sealed on the vertical support 71 While being coupled to and supported, the inner circumferential surface of the coil part 79b is spaced apart from the magnet 79a and the outer circumferential surface is spaced apart from the inner circumferential surface of the pipe 60 .

Through this, when the magnet 79a rotates, heat is generated in the coil part 79b to heat the fluid flowing inside the pipe 60, thereby preventing the water pipe 1 or the pipe 60 from freezing in winter. It can be prevented.

Of course, in some cases, a separate heating wire may be installed in the pipe 60 to heat the heating wire using electricity generated in the self-power generation module 70, thereby preventing freezing and bursting.

The structure in which the blade 73 is folded by the flow rate may be applied to the third rotary shaft 78 and used.

Since other matters are the same as those of the fourth embodiment, a detailed description thereof will be omitted.

6th embodiment

The fifth embodiment has a difference in the configuration and structure of the self-power generation module 70 compared to the fourth embodiment, and this will be mainly described.

The self-powered module 70 includes a vertical support 71, a third rotary shaft 78, a blade 73, a magnet 79a, and a coil unit 79b.

The vertical support 71 is disposed inside the pipe 60 in a vertical direction.

The third rotating shaft 78 is connected to the vertical support 71 in the horizontal direction and rotates.

The blade 73 is coupled to the end of the third rotation shaft 78 and rotates together with the third rotation shaft 78, and is rotated by the fluid flowing inside the pipe 60.

The magnet 79a is coupled to the end of the rotating blade 73.

Therefore, when the blade 73 rotates, the magnet 79a rotates together.

The coil part 79b has a ring shape, is disposed outside the magnet 79a, and is connected to the battery 13.

When the blade 73 rotates, the magnet 79a rotates together, and electricity is generated in the coil part 79b disposed outside the magnet 79a.

Since other matters are the same as those of the fourth or fifth embodiment, a detailed description thereof will be omitted.

The remote water meter reading terminal of the present invention is not limited to the above-described embodiment, and can be implemented with various modifications within the scope permitted by the technical spirit of the present invention.

1: water pipe,
10: main body, 11: input unit, 12: transmitter, 13: battery, 14: earthquake sensor, 15: humidity sensor,
20: fastening member, 21: coupling surface, 22: close contact, 23: first wire, 24: rack gear, 25: pinion gear, 26: torsion spring, 27: second wire, 28: first spring,
30: connection detection sensor,
40: control unit,
50: fixing member.
60: pipe,
70: self-powered module, 71: vertical support, 72: horizontal support, 73: blade, 74: generator, 75: first rotation shaft, 76: second rotation shaft, 77: bevel gear, 78: third rotation shaft, 79a: Magnet, 79b: coil part,
80: Rotation sensor.

Claims (7)

A hollow pipe connected to the water pipe;
a body mounted outside the pipe;
an input unit mounted on the main body to receive data of the water pipe flowmeter;
a transmitter mounted on the main body and transmitting the data received through the input unit to a server;
a battery mounted inside the main body;
a self-power generation module coupled to the pipe and generating electricity by the fluid flowing inside the pipe;
a fastening member coupling the main body to the water pipe;
a coupling detection sensor coupled to the main body and detecting whether the coupling member is coupled to the water pipe;
a controller for controlling the input unit and the transmitter;
An earthquake detection sensor mounted on the main body; including,
When the fastening sensor detects that the fastening member is coupled to the water pipe, the control unit operates the input unit and the transmitter,
When the fastening sensor detects that the fastening member is separated from the water pipe while the input unit and the transmitter are operating, the control unit transmits a theft signal to the server through the transmitter,
The electricity generated in the self-generation module is charged in the battery and then supplied with electricity to the input unit and the transmitter to operate,
The self-powered remote water meter reading terminal, characterized in that, when the connection detection sensor detects that the fastening member is coupled to the water pipe, the control unit operates the earthquake detection sensor. In claim 1,
The self-powered module,
a vertical support placed inside the pipe;
A horizontal support connected in the horizontal direction from the vertical support
a blade rotatably coupled to an end of the horizontal support and rotated by the fluid flowing inside the pipe;
a generator mounted outside the pipe and connected to the battery;
a first rotating shaft mounted inside the vertical support and having an end disposed inside the generator;
a second rotating shaft mounted inside the horizontal support and rotating together with the rotation of the blade;
A bevel gear unit connecting the first rotational shaft and the second rotational shaft;
When the second rotational shaft is rotated by the blade, the first rotational shaft rotates by the bevel gear part and operates the generator to generate electricity. In claim 1,
The self-powered module,
a vertical support placed inside the pipe;
a third rotating shaft that is connected in the horizontal direction from the vertical support and rotates;
a blade coupled to an end of the third rotating shaft, rotating together with the third rotating shaft, and rotating by the fluid flowing inside the pipe;
a magnet coupled to the third rotating shaft;
It is made up of a ring shape and disposed outside the magnet, and a coil part connected to the battery; including,
When the third rotational shaft is rotated by the blade, the magnet rotates together with the third rotational shaft and electricity is generated in the coil part disposed outside the magnet. In claim 3,
The coil part is coupled to and supported by the vertical support in a sealed state,
Self-powered remote water meter reading terminal, characterized in that the inner circumferential surface of the coil part is spaced apart from the magnet and the outer circumferential surface is spaced apart from the inner circumferential surface of the pipe. In claim 1,
The self-powered module,
a vertical support placed inside the pipe;
a third rotating shaft that is connected in the horizontal direction from the vertical support and rotates;
a blade coupled to an end of the third rotating shaft, rotating together with the third rotating shaft, and rotating by the fluid flowing inside the pipe;
a magnet coupled to an end of the blade;
It is made up of a ring shape and disposed outside the magnet, and a coil part connected to the battery; including,
Self-powered remote water meter reading terminal, characterized in that when the blade rotates, the magnet rotates together and electricity is generated in the coil part disposed outside the magnet. According to any one of claims 3 to 5,
Self-powered remote water meter reading terminal, characterized in that when the magnet rotates, heat is generated in the coil part to heat the fluid flowing inside the pipe. The method according to any one of claims 2 to 5,
A rotation sensor for detecting the rotation of the blade; further comprising,
If the rotation of the blade is detected by the rotation sensor but the battery is not charged, the control unit transmits an error signal of the self-power generation module to the server through the transmitter. meter reading terminal.