KR101545684B1 - Power ganaeration for water service pipe usig the water power - Google Patents

Abstract

The present invention relates to a power generation device for water service pipes using a water pressure comprising: a cylindrical housing interposed between water service pipes and having a first inlet for introducing liquid from one water service pipe and a first outlet for discharging the introduced liquid to the other water service pipe; a valve unit cylindrically arranged inside the housing on the same central axis as a central axis of the housing and having a valve body rotated by a water pressure, a plurality of second inlets through which the liquid introduced into the housing is introduced into the valve body, and a second outlet for discharging the liquid to the housing from the valve body; a stator arranged inside the housing; a rotation unit connected to the valve body to rotate together and having a rotor installed corresponding to the stator and a plurality of rotating blades formed from a rotary shaft of the rotor in a circumferential direction; and magnets for producing electricity by the rotation of the rotor. The present invention can increase the water pressure to produce electric energy even in the water service pipes with a low water pressure by gradually reducing the diameter of the second inlets to which the liquid with the low water pressure is introduced and controlling the liquid to be stagnated in the first inlet for a predetermined time through the rotation of the valve body.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a power generator for a water pipe,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a power generator for a water pipe using a water pressure, and more particularly, to a power generator for a water pipe using a water pressure that can increase a water pressure to produce electric energy even in a water pipe with a low water pressure.

Generally, electric power generation methods that generate electric energy include thermal power generation using fossil fuel as a main material, nuclear power generation using nuclear fission, wind power using wind direction, solar power using solar light, Tidal power generation, and hydropower generation that develops due to a drop in the flow of the dam. In the case of such thermal power generation, there is a problem that environmental pollution such as resource depletion problem and greenhouse gas emission is generated because the main raw materials must be continuously supplied. In the case of nuclear power generation, as in the case of thermal power generation, there are problems such as depletion of main raw materials, radiation leakage due to nuclear reaction, and disposal of nuclear waste. In the case of wind power generation, it is impossible to generate electricity when the wind does not blow, and sunlight can not be constantly developed due to changes in daytime, nighttime and climate. In addition, in the case of tidal power generation, it can be developed only when there is a tidal difference. Such a development method is disadvantageous in that it can not be constantly developed due to different problems. In order to overcome these disadvantages, recently, many devices have been invented that produce electric energy through water pressure generated by water flowing in a river or a water pipe, and use the electric energy directly or fill the battery and use it in a place where electric energy is required .

Among them, there is a prior art 'Korean Patent Registration No. 10-0578452', an electric energy generator using water pressure of a water pipe ', which includes a turbine blade for converting hydraulic pressure into rotary motion to obtain power, a turbine 1. A turbine rotor comprising: a turbine shaft; a unit including a shaft and a generator for generating electric energy in association with the turbine shaft; an induction plate for guiding water flowing in one side of the unit; And a hydraulic pressure difference housing for guiding a hydraulic pressure deviation to the upper and lower sides of the hydraulic pressure chamber.

In addition, there is a first water pressure rising pipe formed in the prior art 'Korean Patent Registration No. 10-1092123' where the inner diameter becomes narrower toward the outlet side in the electricity generating device using water pressure of the water supply and sewage pipe, It should be installed in a water pipe with very high water pressure to rise.

Therefore, in the conventional invention having such a configuration, it is difficult to produce electric energy because the turbine blade does not rotate or rise in the direction of the tee pipe when the water pressure is low or the flow rate is low. There is a limit.

Korea Patent Office Registration No. 10-0578452 Korea Patent Office Registration No. 10-1092123

SUMMARY OF THE INVENTION It is therefore an object of the present invention to provide an apparatus and a method for controlling a flow rate of a liquid in a water pipe, the method comprising: gradually reducing a diameter of a second inflow pipe into which a low- A power generating device for a water pipe using a water pressure capable of increasing a water pressure so as to produce electric energy.

The above object can be accomplished by providing a water pump comprising: a cylindrical housing provided between a water pipe and having a first inlet through which liquid flows from the water pipe and a first outlet through which the introduced liquid is discharged to the water pipe; A valve body rotatably driven by water pressure and arranged in a cylindrical shape in the housing with the same central axis as the central axis of the housing; a plurality of second inlets for allowing the liquid introduced into the housing to flow into the valve body; And a second outlet for discharging liquid from the valve body to the housing; A stator disposed within the housing; A rotating unit connected to the valve body and rotating together and corresponding to the stator, and a plurality of rotating blades formed along the diameter of the rotating shaft of the rotor; And a magnet capable of producing electricity by rotation of the rotor.

Preferably, the ratio of the cross sectional area of the plurality of second inlets to the first inlet is in a range of 1: 1.5 to 3, and the diameter of the second inlet is gradually increased along the inflow direction of the liquid so that the water pressure of the liquid increases. And the ratio of the cross-sectional area of the second inlet where the diameter gradually decreases to the area where the liquid is introduced and the area where the liquid is discharged is preferably 1: 0.5 to 0.8.

Preferably, the plurality of second inlets are formed by a multiple of 2, and the rotor blade has a central region protruding along the rotational direction of the rotor.

According to the structure of the present invention described above, the diameter of the second inflow pipe into which the low-pressure liquid flows is gradually reduced, and the liquid is adjusted to be filled in the first inflow pipe through the rotation of the valve body for a predetermined time, It is possible to increase the water pressure so as to produce electric energy even in a low water pipe.

1 is a front view of a power generator for a water pipe according to an embodiment of the present invention,
2 is a cross-sectional view of Fig.

Hereinafter, a water power generation power generator 10 according to an embodiment of the present invention will be described in detail.

1 and 2, the water power generation power generation apparatus 10 includes a housing 100, a valve unit 300 disposed in the housing 100, a rotation unit (not shown) that rotates together with the valve unit 300 500, a stator 700, and a magnet 900.

The housing 100 has a cylindrical shape and is interposed between water pipes through which a low-pressure liquid flows. The housing 100 has a first inlet 110 through which liquid flowing along the water pipe flows, and a first outlet 110 through which the introduced liquid is discharged back to the water pipe 130). Here, the first inlet 110 and the first outlet 130 are tightly coupled to the water pipe, and a female screw or a male screw is formed to prevent leakage, and a corresponding female screw or male screw is also formed in the water pipe.

Preferably, the first inlet 110 formed in the housing 100 is formed in an area above the first outlet 130. The liquid introduced from the first inlet 110 is rotated to generate electricity and then is moved to the first outlet 130 region by gravity and is discharged to the water pipe through the first outlet 130 .

The valve unit 300 disposed in the housing 100 includes a valve body 310 having a cylindrical shape and a second inlet 330 and a second outlet 350 formed in the valve body 310, . The valve body 310 is rotatably driven by the hydraulic pressure of the liquid introduced into the valve unit 300 by arranging the central axis at the same position as the central axis of the housing 100.

The second inlet 330 coupled to the valve body 310 is formed of a plurality of liquids and the liquid introduced through the first inlet 110 flows into the valve body 310 through the second inlet 330. It is preferable that the plurality of second inlets 330 are formed in a multiple of two, that is, an even number. In this case, it is structurally stable to form even number of odd numbers when designing the power generation apparatus 100, to be.

The water pressure of the liquid is low because it is used in a water pipe having a low water pressure in the present invention. When the liquid is directly introduced into the valve body 310, the liquid has a force enough to rotate the rotary vane 510 in the valve body 310 So that it is not easy to rotate the rotary vane 510. Therefore, it is preferable that the liquid introduced through the first inlet 110 is increased to a certain degree and then the water is introduced into the valve body 310 after the water pressure is increased. To this end, the second inlet 330 is connected to the first inlet 110 It is preferable that the diameter is small. The ratio of the total cross-sectional area of the plurality of second inlets 330 to the cross-sectional area of the first inlet 110 is 1: 1.5 to 3, and the ratio of the total cross-sectional area of the plurality of second inlets 330 to the cross- If the cross-sectional area ratio of the inlet 110 is less than 1.5, it is difficult to increase the water pressure. If the ratio is more than 3, the amount of liquid discharged may be less than the amount of the liquid to be introduced.

When the valve body 310 is rotated and the second inlet 330 is disposed in the region of the first inlet 110, the liquid is introduced into the second inlet 330 and the second inlet 330 is connected to the first inlet 330 110, the liquid is accumulated in the region of the first inlet 110. Then, when the second inlet 330 is disposed in the first inlet 110 by rotation of the valve body 310, the accumulated liquid flows into the second inlet 330 with a high water pressure. That is, when the plurality of second inlets 330 formed in the valve body 310 are not disposed in the first inlet 110, the liquid is stored in the first inlet 110 and the water pressure is increased, When the second inlet 330 is disposed in the first inlet 110, the liquid with increased water pressure flows into the second inlet 330 and rotates the inner rotor 510 at a higher water pressure.

In order to increase the water pressure of the liquid, not only the valve body 310 may be rotated, but the diameter of the second inlet 330 may be gradually decreased. As the diameter of the second inlet 330 gradually decreases along the liquid inflow direction, the water pressure in the second order increases, and the rotary vane 510 rotates more strongly, thereby facilitating power generation. The ratio of the cross-sectional area of the second inlet 330 to the area of the liquid to be discharged and the area to be discharged is preferably 1: 0.5 to 0.8. When the cross-sectional area ratio of the discharged area is less than 0.5, The amount of liquid is too small to discharge the liquid smoothly, and when it exceeds 0.8, the effect of increasing the water pressure is insignificant.

The second outlet 350 is disposed at a lower portion of the valve body 310 to discharge the liquid to the first outlet 130. The second outlet 350 may be integrally formed with the valve body 310 and rotated together with the second outlet 350. Alternatively, the second outlet 350 may be fixed separately.

The rotating unit 500 connected to the rotating valve body 310 and rotating together includes a rotor 530 and a rotating blade 510. The liquid flowing through the valve body 310 is a liquid with a high water pressure, thereby rotating the plurality of rotating blades 510. The rotor 530 connected to the rotary vane 510 rotates. Here, the rotary vane 510 is formed along the diameter of the rotary shaft of the rotor 530, and the shape of the rotary vane 510 is preferably a curved shape in the central area along the rotation direction of the rotor 530. When the central region of the rotary vane 510 protrudes, the liquid is gathered in the central region, and the water pressure becomes stronger than when the rotary vane 510 is straight, so that the rotation speed increases.

The rotor 530 disposed in the valve body 310 rotates together with the valve body 310. The valve body 310 and the rotor 530 are coupled to each other to enable such driving. More preferably, the valve body 310 and the rotor 530 are integrally formed.

A stator 700 is provided in the housing 100 in correspondence to the rotor 530 and a magnet 530 is provided between the stator 700 and the rotor 530 to enable electricity to be produced by the rotation of the rotor 530. [ (900) is installed. Also, although not shown in the stator 700, a generator is connected, so that the rotational force of the rotor 530 is transmitted to the generator to finally produce electricity. Here, the magnet can be any of a magnet of a power generation type such as an electromagnet, a permanent magnet, or the like.

Conventional power generators for water supply systems are mainly installed in water pipes where high water pressure is formed. However, in the present invention, not only the diameter of the second inlet 330 gradually decreases but also the inflow of liquid into the second inlet 330 is controlled while the valve body 310 rotates to further increase the water pressure of the liquid. Such a power generation apparatus 10 of the present invention can be easily used for a water pipe having a low water pressure.

10: Power generator 100: Housing
110: first inlet 130: first outlet
300: valve unit 310: valve body
330: second inlet port 350: second outlet port
500: rotating unit 510: rotating blade
530: Rotor 700: Stator
900: Magnet

Claims (6)

1. A power generator for a water pipe using a water pressure,
A cylindrical housing interposed between the water pipes and having a first inlet through which the liquid flows from the water pipe and a first outlet through which the introduced liquid is discharged to the water pipe;
A valve body rotatably driven by water pressure and arranged in a cylindrical shape in the housing with the same central axis as the central axis of the housing; a plurality of second inlets for allowing the liquid introduced into the housing to flow into the valve body; And a second outlet for discharging liquid from the valve body to the housing;
A stator disposed within the housing;
A rotating unit connected to the valve body and rotating together and corresponding to the stator, and a plurality of rotating blades formed along the diameter of the rotating shaft of the rotor;
And a magnet for producing electric power by rotation of the rotor. The method according to claim 1,
Wherein a ratio of a total cross-sectional area of the plurality of second inlets to a cross-sectional area of the first inlet is 1: 1.5 to 3. The method according to claim 1,
Wherein the second inlet gradually decreases in diameter along the inflow direction of the liquid to increase the hydraulic pressure of the liquid. The method of claim 3,
Wherein a ratio of a cross-sectional area of a region in which the liquid is introduced to a region in which the liquid is discharged is in a range of 1: 0.5 to 0.8, the second inlet being gradually reduced in diameter. The method according to claim 1,
And the plurality of second inlets are formed in multiples of two. The method according to claim 1,
Wherein the rotary blade has a central region protruded along the rotation direction of the rotor.

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