CN220273457U - Pipeline fluid kinetic energy acquisition device - Google Patents

Abstract

The utility model discloses a pipeline fluid kinetic energy acquisition device, which comprises a shell module and a power generation module, wherein the power generation module is arranged on the shell module, the shell module comprises a first shell and a second shell, the first shell and the second shell are fixedly connected, and the power generation module is positioned between the first shell and the second shell; the power generation module includes a rotor unit, a first stator unit, and a second stator unit. According to the pipeline fluid kinetic energy acquisition device disclosed by the utility model, the rotor unit is driven to rotate by the fluid flow in the pipeline, then the stator units positioned on two sides of the rotor unit are combined to perform electromagnetic power generation, and finally the transmission wire is used for supplying power to the external device, so that the pipeline fluid kinetic energy acquisition device has the advantages of stable structure, high practicability, high safety and the like.

Description

Pipeline fluid kinetic energy acquisition device

Technical Field

The utility model belongs to the technical field of pipeline kinetic energy collection, and particularly relates to a pipeline fluid kinetic energy collection device.

Background

At present, the network of tap water, petroleum, natural gas, chemical liquid medicine and the like often needs to carry out on-line diagnosis of water quality detection, particulate matter detection, leakage point detection, flow detection, pressure, temperature and the like. In the on-line diagnosis process and the result transmitting process, power needs to be supplied in time, so that the problem of power consumption is often encountered.

Wind energy, solar energy and the like are easy to be damaged naturally or artificially in the field, urban capacity is influenced by wind energy and solar energy in urban areas, the electric safety risk of a power connection wire is high, the storage battery is often used for supplying power at present by combining the factors, but a great deal of work such as inspection, battery replacement, charging, battery maintenance and the like can be brought to people due to the use environment and the electric quantity problem and quality problem of the storage battery, and the detection result is also influenced to a certain extent.

Accordingly, the above problems are further improved.

Disclosure of Invention

The utility model mainly aims to provide a pipeline fluid kinetic energy acquisition device which drives a rotor unit to rotate through fluid flowing in a pipeline, then combines stator units positioned on two sides of the rotor unit to perform electromagnetic power generation, and finally supplies power to the external device through a transmission wire.

In order to achieve the above object, the present utility model provides a pipe fluid kinetic energy collection device, comprising a housing module and a power generation module, wherein the power generation module is mounted on the housing module, and the power generation module comprises:

the housing module comprises a first housing and a second housing, the first housing and the second housing are fixedly connected, and the power generation module is positioned between the first housing and the second housing;

the power generation module includes a rotor unit, a first stator unit and a second stator unit, the first stator unit being located between the rotor unit and the first housing and the second stator unit being located between the rotor unit and the second housing, wherein;

the rotor unit comprises a turbine and first magnetic steels, wherein the first magnetic steels are uniformly distributed and arranged at (the edge of) the turbine, and are preferably circularly distributed;

the first stator unit comprises a first stator base, a first circuit board, a first magnetic conducting ring (magnetic conducting effect of a coil) and a plurality of first coils (each coil is a small cylinder, and the coils are wound around the coils), wherein the first magnetic conducting ring is fixedly arranged on one side of the first stator base, which is close to the first shell, and the first coils are arranged between the first stator base and the first magnetic conducting ring in a distributed manner (preferably in a circular distribution), and the first circuit board is arranged on one side of the first magnetic conducting ring, which is far away from the first stator base;

the second stator unit comprises a second stator seat, a second circuit board, a second magnetic conduction ring (magnetic conduction effect of the coil) and a plurality of second coils (each coil is a small cylinder, and coils are wound around), the second magnetic conduction ring is fixedly arranged on one side of the second stator seat, which is close to the second shell, and the second coils are arranged between the second stator seat and the second magnetic conduction ring in a distributed mode (preferably in a circular mode), and the second circuit board is arranged on one side, which is far away from the second stator seat, of the second magnetic conduction ring.

As a further preferable technical scheme of the above technical scheme, the turbine is provided with a first magnetic steel installation position, and the first magnetic steel is fixedly installed on the first magnetic steel installation position (the first magnetic steel is provided with a south pole and a north pole, which are arranged at intervals).

As a further preferable technical scheme of the above technical scheme, one end of the first housing far away from the second housing is provided with a first pipeline connecting end, and one end of the second housing far away from the first housing is provided with a second pipeline connecting end.

As a further preferable technical scheme of the above technical scheme, the power generation module is further provided with a first mounting seat and a second mounting seat, and the rotor unit, the first stator unit and the second stator unit are all located between the first mounting seat and the second mounting seat.

As a further preferable technical scheme of the technical scheme, the second mounting seat is provided with a transmission wire.

As a further preferable technical scheme of the technical scheme, the magnetic rod is arranged between the first coil and the second coil (on one hand, the magnetic rod can enable the coils to generate more magnetic force to increase the generated energy, and on the other hand, the magnetic rod is matched with the magnetic conducting ring to firmly install each coil on the coil groove part of the stator seat, so that the stator seat is not easy to shake).

Drawings

Fig. 1 is a schematic structural view of a pipe fluid kinetic energy collecting device according to the present utility model.

Fig. 2 is an exploded view of a pipe fluid kinetic energy collection device of the present utility model.

Fig. 3 is a schematic structural diagram of a second stator seat and a second magnetic ring of the pipe fluid kinetic energy collecting device of the present utility model.

Fig. 4 is a schematic structural diagram of a second stator base of a pipe fluid kinetic energy collecting device according to the present utility model.

The reference numerals include: 100. a housing module; 110. a first housing; 111. a first pipe connection end; 120. a second housing; 121. a second pipe connection end; 200. a power generation module; 210. a rotor unit; 211. a turbine; 212. a first magnetic steel; 213. a first magnetic steel installation position; 220. a first stator unit; 221. a first stator base; 222. a first circuit board; 223. a first magnetic ring; 224. a first coil; 225. a magnetic rod; 230. a second stator unit; 231. a second stator base; 232. a second circuit board; 233. a second magnetic ring; 234. a second coil; 240. a first mount; 250. a second mounting base; 251. and a transmission wire.

Detailed Description

The following description is presented to enable one of ordinary skill in the art to make and use the utility model. The preferred embodiments in the following description are by way of example only and other obvious variations will occur to those skilled in the art. The basic principles of the utility model defined in the following description may be applied to other embodiments, variations, modifications, equivalents, and other technical solutions without departing from the spirit and scope of the utility model.

The utility model discloses a pipeline fluid kinetic energy acquisition device, and the following describes a specific embodiment of the utility model further by combining with a preferred embodiment.

In embodiments of the present utility model, those skilled in the art will note that the pipes, fluids, etc. to which the present utility model relates may be considered prior art.

Preferred embodiments.

As shown in fig. 1 to 4, the utility model discloses a pipeline fluid kinetic energy collecting device, which comprises a housing module 100 and a power generation module 200, wherein the power generation module 200 is installed on the housing module 100, and the utility model comprises the following components:

the housing module 100 includes a first housing 110 and a second housing 120 and the first housing 110 and the second housing 120 are fixedly connected, and the power generation module 200 is located between the first housing 110 and the second housing 120;

the power generation module 200 includes a rotor unit 210, a first stator unit 220, and a second stator unit 230, the first stator unit 220 being located between the rotor unit 210 and the first housing 110 and the second stator unit 230 being located between the rotor unit 210 and the second housing 120, wherein;

the rotor unit 210 includes a turbine 211 and first magnetic steels 212, where the first magnetic steels 212 are uniformly distributed and mounted at (the edge of) the turbine 211, preferably in a circular distribution;

the first stator unit 220 includes a first stator base 221, a first circuit board 222, a first magnetic conductive ring 223 (magnetic conductive effect of the coil) and a plurality of first coils 224 (each coil is a small cylinder, and is wound with a coil around), the first magnetic conductive ring 223 is fixedly mounted on one side of the first stator base 221 close to the first housing 110, and the first coils 224 are distributed and mounted between the first stator base 221 and the first magnetic conductive ring 223 (preferably in circular distribution), and the first circuit board 222 is mounted on one side of the first magnetic conductive ring 223 away from the first stator base 221;

the second stator unit 230 includes a second stator seat 231 (a turbine is mounted on the second stator seat so as to rotate), a second circuit board 232, a second magnetic conductive ring 233 (magnetic conductive effect of the coil), and a plurality of second coils 234 (each coil is a small cylinder around which the coil is wound), the second magnetic conductive ring 233 is fixedly mounted on one side of the second stator seat 231 near the second housing 120, and the second coils 234 are mounted between the second stator seat 231 and the second magnetic conductive ring 233 (preferably in a circular distribution), and the second circuit board 232 is mounted on one side of the second magnetic conductive ring 233 far from the second stator seat 231.

Specifically, the turbine 211 is provided with a first magnetic steel mounting position 213, and the first magnetic steel 212 is fixedly mounted on the first magnetic steel mounting position 213 (the first magnetic steel is provided with a south pole and a north pole, which are arranged at intervals).

More specifically, the first housing 110 is provided with a first pipe connection end 111 at an end remote from the second housing 120 and the second housing 120 is provided with a second pipe connection end 121 at an end remote from the first housing 110.

Further, the power generation module 200 is further provided with a first mounting seat 240 and a second mounting seat 250, and the rotor unit 210, the first stator unit 220 and the second stator unit 230 are all located between the first mounting seat 240 and the second mounting seat 250.

Further, the second mounting base 250 is provided with a transmission wire 251.

Preferably, the magnetic rod is installed in the middle of first coil with the second coil (on the one hand the magnetic rod can make the coil produce more magnetic force, increases the generated energy, on the other hand the magnetic rod cooperates the magnetic conduction circle and firmly installs each coil in the coil recess portion of stator seat, is difficult for rocking).

As shown in fig. 4, the second stator base is provided with a plurality of grooves for mounting the second coil, and the first stator base is provided with a plurality of grooves for mounting the first coil.

The principle of the utility model is as follows:

install this device between the pipeline through first pipeline link and second pipeline link, when leading to in the pipeline has fluid (including gas and the liquid etc. that flow), the turbine that is equipped with the magnet steel rotates, then because the first stator unit that is located the turbine both sides and second stator unit all are equipped with a plurality of distributed coils, and then cut the magnetism and feel the line, then the electric energy that generates is respectively through the transmission wire power supply after first circuit board and second circuit board handle, this device is fit for including solenoid valve in passive pipeline, alarm device and wireless data transmission device etc. power supply, and then realize the supply of electric energy, and need not to route and carry out commercial power supply, simply make things convenient for high-efficient. And because two stator units are arranged, when any stator unit fails, one stator unit can work normally, electricity can be generated to supply power, the fault tolerance rate is improved, the power supply is ensured, and an alarm device can be arranged, and when any stator unit fails and does not work, the remote alarm is carried out through the wireless transmission device.

It should be noted that technical features such as pipes and fluids related to the present application should be considered as the prior art, and specific structures, working principles, and control manners and spatial arrangements of the technical features may be selected conventionally in the art, and should not be considered as the point of the present application, which is not further specifically described in detail herein.

Modifications of the embodiments described above, or equivalents of some of the features may be made by those skilled in the art, and any modifications, equivalents, improvements or etc. within the spirit and principles of the present utility model are intended to be included within the scope of the present utility model.

Claims (6)

1. The utility model provides a pipeline fluid kinetic energy collection system which characterized in that, includes shell module and power generation module, power generation module install in shell module, wherein:

the housing module comprises a first housing and a second housing, the first housing and the second housing are fixedly connected, and the power generation module is positioned between the first housing and the second housing;

the power generation module includes a rotor unit, a first stator unit and a second stator unit, the first stator unit being located between the rotor unit and the first housing and the second stator unit being located between the rotor unit and the second housing, wherein;

the rotor unit comprises a turbine and first magnetic steel, and the first magnetic steel is uniformly distributed and installed on the turbine;

the first stator unit comprises a first stator base, a first circuit board, a first magnetic conducting ring and a plurality of first coils, wherein the first magnetic conducting ring is fixedly arranged on one side of the first stator base, which is close to the first shell, and the first coils are arranged between the first stator base and the first magnetic conducting ring in a distributed manner, and the first circuit board is arranged on one side of the first magnetic conducting ring, which is far away from the first stator base;

the second stator unit comprises a second stator seat, a second circuit board, a second magnetic conduction ring and a plurality of second coils, wherein the second magnetic conduction ring is fixedly installed on one side, close to the second shell, of the second stator seat, the second coils are installed between the second stator seat and the second magnetic conduction ring in a distributed mode, and the second circuit board is installed on one side, far away from the second stator seat, of the second magnetic conduction ring.

2. The device of claim 1, wherein the turbine is provided with a first magnet mounting location, and the first magnet is fixedly mounted to the first magnet mounting location.

3. A pipeline fluid kinetic energy harvesting device as defined in claim 2, wherein the end of the first housing remote from the second housing is provided with a first pipeline connection end and the end of the second housing remote from the first housing is provided with a second pipeline connection end.

4. A pipe fluid kinetic energy harvesting device as defined by claim 3, wherein the power generation module is further provided with a first mount and a second mount, the rotor unit, the first stator unit, and the second stator unit each being located between the first mount and the second mount.

5. A pipe fluid kinetic energy harvesting apparatus as defined by claim 4, wherein the second mount is provided with a transmission wire.

6. A pipe fluid kinetic energy harvesting device as defined by claim 1, wherein a magnetic rod is mounted intermediate the first coil and the second coil.