WO2019127812A1

WO2019127812A1 - Power generation auxiliary device forming negative pressure closed loop

Info

Publication number: WO2019127812A1
Application number: PCT/CN2018/074448
Authority: WO
Inventors: 郑毅强
Original assignee: 郑毅强
Priority date: 2017-12-28
Filing date: 2018-01-29
Publication date: 2019-07-04
Also published as: CN109973156A

Abstract

A power generation auxiliary device forming a negative pressure closed loop, comprising combination of a blowing mechanism (50) and a flow path module (10). The flow path module (10) is a pipeline structure defining a chamber (13) and is provided with a first end (11) and a second end (12) which are separately connected to the blowing mechanism (50) to jointly form a closed loop structure; the chamber (13) of the flow path module (10) is provided with at least two power generation modules (20) which draw a fluid by cooperating with the blowing mechanism (50), such as gas or liquid, to move in the chamber (13) of the flow path module (10) from the first end (11) or the second end (12) to the second end (12) or the first end (11); electric energy is generated by the power generation modules (20), and a negative pressure effect is generated between adjacent power generation modules (20), and a circulation loop mechanism for controlling the fluid is established, so that energy sources or fluid power can be recycled, energy loss can be reduced, and the power generation efficiency can be relatively improved.

Description

Power generation auxiliary device forming a negative pressure closed loop

Technical field

The invention relates to a power generation auxiliary device for forming a negative pressure closed circuit; in particular to a combination of a flow path module and a stirring mechanism, which constitutes a closed circuit structure to facilitate reuse of a fluid to generate electric energy through a power generation module.

Background technique

It has been a prior art to apply air flow through a windmill or agitating mechanism, through the mechanical energy of the rotation of the blade, to drive the wire coil of the generator set to generate magnetic excitation and convert it into a power output device. For example, Taiwan Province No. 100139581 "Closed Wind Power Equipment", No. 98210701 "Wind Power Generation Structure", No. 95148715 "Wind Power Plant" patent case, etc., provides a typical embodiment.

The prior art also discloses a number of different structural types or wind power generation structures that use complex transmission mechanisms to control the wind deflector; for example, Taiwan Taiwan No. 972109733 "Structural Improvement of Vertical Composite Wind Turbines", No. 98206677 "Horizontal-axis wind turbine with rotatable tower", multi-segment folding and telescopic fan blade structure, and the adjustment of blade length with the hydraulic rod, No. 93200993 "Structure of wind power windmill", using motor and rotating shaft The control group, the "wind power generation device" patent No. 96202060, which controls the direction of the wind deflector and the blade, provides a feasible embodiment.

A subject of structural design and operational applications for such wind power plants is that they do not consider mechanisms for recovering or reusing residual energy (eg, wind or fluid forces) to reduce energy losses or increase power generation efficiency; Not what we expected.

Representatively, these references show situations in the use and structural design of wind power plants or their associated combined systems. If the redesign is to consider the structural combination of the wind power plant and related components, as well as the application described above, the configuration is different from the prior art, and its use form can be changed, which is different from the prior art. In essence, the recovery or reuse of energy sources can be achieved to reduce energy losses or to increase power generation efficiency; none of these topics are specifically taught or disclosed in the above references.

Summary of the invention

Accordingly, it is a primary object of the present invention to provide a power generating auxiliary device for forming a vacuum closed circuit comprising a combination of a agitating mechanism (e.g., a blower or a pump) and a flow path module. The flow path module is a pipeline structure defining a chamber, having a first end and a second end respectively connected to the agitating mechanism to jointly form a closed loop structure; and the chamber of the flow path module is provided with at least two power generation The module cooperates with the agitating mechanism to move the fluid (for example, air or liquid) from the first end (or the second end) toward the second end (or the first end) to move in the chamber of the flow path module through the power generation module Generating electric energy and causing agitation by adjacent negative power generating modules to reduce energy loss; and establishing a fluid flow path to form a circulation loop mechanism to obtain energy (or wind) recovery and reuse, Multiplying the ground to improve power generation efficiency.

According to the power generating auxiliary device for forming a vacuum closed circuit according to the present invention, the flow path module is a combination of at least two pipes, each of which is provided with a connecting pipe, and constitutes at least two interconnected U-shaped pipes structure. And, the agitating mechanism is combined with a fluid input portion, and the fluid can be replenished into the agitation mechanism via the fluid input portion according to the use situation.

According to the power generation auxiliary device for forming a vacuum closed circuit according to the present invention, a flow guiding device can be disposed in the fluid chamber before entering the power generation module to provide fluid to enter each power generation module in an optimal direction, thereby further improving power generation efficiency.

According to the power generating auxiliary device for forming a vacuum closed circuit according to the present invention, at least a part of the overall flow path module may be provided with a heat dissipating device for dissipating residual heat generated by the internal unit and the fluid after being driven. Avoid the pressure difference resistance caused by the increase of the loop temperature, so that the flow of the whole fluid is smoother.

DRAWINGS

BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is a schematic perspective view of the present invention.

Figure 2 is a plan view of the planar structure of Figure 1; showing a top view of the flow path module combination agitating mechanism, the arrow portion of the figure depicting the fluid motion.

3 is a schematic view of another planar structure of FIG. 1; a top view of the flow path module combination agitating mechanism is depicted, and the arrow portion of the figure shows the fluid motion.

Figure 4 is a schematic plan view of the structure of Figure 1; showing a bottom view of the flow path module combination agitating mechanism, the arrow portion of the figure depicting the fluid motion.

Figure 5 is a partial schematic view of the present invention; depicting the power generation module and fluid motion.

Figure 6 is a partial structural view of another possible embodiment of the present invention, particularly showing a flow guiding device and a heat sink.

Description of the reference signs:

10 flow module

11 first end

12 second end

13 chamber

13a first chamber

13b second chamber

13c third chamber

15 pipeline

16 connecting tube

20 power generation module

21 first power generation module

22 second power generation module

23 third power generation module

25 rotating blades

50 agitating mechanism

60 fluid input

70 flow guiding device

80 heat sink.

Detailed ways

Referring to FIG. 1, the power generation auxiliary device for forming a vacuum closed circuit of the present invention comprises a combination of a first-class road module and an agitation mechanism, which are respectively indicated by

reference numerals

10 and 50. The flow path module 10 is a combination of at least two lines 15, each of which is provided with a connecting tube 16 to form at least two interconnected U-shaped piping structures.

In the embodiment taken, the flow path module 10 (or the line 15) defines a chamber 13 in which at least two power generation modules 20 are disposed; the power generation module 20 is provided with a rotating blade 25 that can be fitted with a fluid ( For example, air or liquid passes through, causing the power generation module 20 to generate electrical energy. And, the flow path module 10 has a first end 11 and a second end 12, which are respectively connected to the agitating mechanism 50 to jointly form a closed loop structure.

The imaginary line portion of the figure shows that the agitating mechanism 50 can incorporate a (wind or liquid) fluid input 60 for personnel to replenish fluid into the agitating mechanism 50 via the fluid input 60 depending on the use. The agitating mechanism 50 can select a blower, a pump, or the like, and is a prior art structure, and thus is not described in detail.

2, 3 and 4 depict the flow path module 10, according to the site environment, at least two pipelines 15 are matched with the connecting pipe 16, and are connected to form a first row of flow path modules 10 (or upper flow path modules), The second row of flow path modules 10 (or lower flow path modules) and/or the majority of the flow path modules 10 .

The arrows in Figures 2, 3 and 4 show the movement of fluid or air flow within the flow path module 10 (or chamber 13). It is assumed that the agitation mechanism 50 squirts the airflow (fluid) inside the flow path module 10 so that the airflow enters the agitation mechanism 50 from the first end 11 of the flow path module 10 (or the first discharge flow path module 10), and the airflow is again The second end 12 enters the flow path module 10 (or the second discharge flow path module 10), is input to the first discharge flow path module 10 via the connection pipe 16, and establishes a closed loop mechanism for controlling the fluid to obtain energy. (or wind) recovery and reuse and reduce energy loss.

Referring to Figure 5, a first end 11 of the conduit 15 and the attachment agitating mechanism 50 is depicted as an illustrative embodiment. For assistance in explanation, at least two power generation modules 20 forming an arrangement configuration in the pipeline chamber 13 are divided into a first power generation module 21, a second power generation module 22, a third power generation module 23, ..., and the first power generation module 21 is used. The chamber 13 between the first end 11 and the first end 11 is defined as a first chamber 13a, and the chamber 13 between the first power generation module 21 and the second power generation module 22 is defined as a second chamber 13b, a second power generation module 22 and The chamber 13 between the third power generation modules 23 is defined as a third chamber 13c.

When the agitating mechanism 50 operates to move the fluid in the pumping line 15, the first chamber 13a is caused to generate a negative pressure, so that the second chamber 13b is relatively formed with a relatively large fluid pressure to generate an assisted pushing fluid from the second chamber. 13b flows into the first chamber 13a; when the fluid enters the first chamber 13a through the first power generating module 21 (or the rotating blade 25), the second chamber 13b generates a negative pressure; therefore, the third is relatively The chamber 13c sequentially forms a large fluid pressure, and enters the second chamber 13b through the second power generating module 22 (or the rotating blade 25).

It can be understood that the fluid entering the first chamber 13a is input into the agitating mechanism 50 via the first end 11, and then injected into the flow path module 10 (or the second row flow path module 10) from the second end 12, following the first The draining path module 10 and the first end 11 are input to the agitating mechanism 50 to jointly establish the closed loop circulation structure described above.

Referring to FIG. 6, since the present invention can be installed in the majority of the power generation module 20 in the integrally formed closed loop to improve the overall power generation efficiency, the working fluid flowing inside the flow path module 10 passes through each power generation. When the module 20 is used, it will cause turbulence phenomenon due to different discharge time and angle after the driving force is pushed. Therefore, if the power is directly pushed into the next power generation module 20 for promotion, the overall energy will be weakened by each other. Therefore, the present invention A person can further provide a flow guiding device 70 in the chamber 13 of the overall fluid flow before each power generating module 20, and guide the fluid to enter the power generating module 20 at an optimal angle and direction, so that each power generation effect is achieved. Best, and eliminate the self-loss caused by turbulence. Furthermore, in order to effectively dissipate residual residual pressure difference resistance that may occur during operation of the overall power generating device, the present invention may further provide a heat dissipating device 80 at at least a partial position of the overall flow path module 10, thereby appropriately dispersing the internal portion. The residual heat generated by the unit and the fluid to drive the operation avoids the flow resistance caused by the differential pressure and affects the overall power generation efficiency.

Typically, this power generation auxiliary device forming a negative pressure closed loop has the following special considerations and advantages over the prior art under the condition of energy saving.

1. The matching form of the flow path module 10, the power generation module 20 and the related components or the agitation mechanism 50 has been redesigned to make it different from the prior art and to change its use and operation state, and is different from the present There are technologies. For example, the flow path module 10 is provided with a first end 11 and a second end 12 respectively pivotally connected to the agitating mechanism 50 to jointly establish a closed loop type capable of generating a negative pressure; the flow path module 10 defines a chamber 13 and configured At least two power generation modules 20; at least two pipelines 15 combined with the connection pipe 16, forming a U-shaped pipeline structure and the like, obviously having an innovative structural design, can reduce the forward impact of the power generation module 20 by the fluid, and relatively Reduce the loss rate of the application process.

2. In particular, the combined structure of the flow path module 10, the power generation module 20, and the agitation mechanism 50, the mechanism by which the fluid circulates through the power generation module 20 to generate electrical energy, and also shows that the same fluid (or reduced energy loss) is maintained. Under the condition, the more the plurality of power generation modules 20 are disposed in the flow path module 10, the total amount of electric energy generated by the power generation module 20 can be increased as much as possible, and the power generation efficiency and the like are relatively increased.

The invention provides an effective power generation auxiliary device for forming a vacuum closed circuit, and the spatial form thereof is also different from the prior art, and has the advantages unmatched in the prior art, and exhibits considerable progress, and has fully complied with the invention. The requirements of the patent.

The above is only the possible embodiments of the present invention, and is not intended to limit the scope of the present invention, and all equivalent changes and modifications made by the claims of the present invention are covered by the scope of the present invention.

Claims

A power generation auxiliary device for forming a vacuum closed circuit, comprising:

a combination of agitating mechanism and flow path module;

The flow path module is a pipeline structure defining a chamber having a first end and a second end respectively connected to the agitating mechanism to jointly form a closed loop structure;

The chamber of the flow path module is provided with at least two power generation modules, and the power generation module is provided with rotating blades; the agitating mechanism is used to spur the fluid, so that the fluid is in the chamber of the flow path module, and a negative pressure is generated between the adjacent power generation modules. And the motion generates electric energy through the power generation module, and establishes a closed loop circuit that controls the fluid to assist power generation through the negative pressure flow.
The power generation auxiliary device for forming a vacuum closed circuit according to claim 1, wherein the flow path module is a combination of at least two pipes, and each of the pipes is provided with a connecting pipe to constitute at least two U-shaped pipe structure connected to each other.
The power generation auxiliary device for forming a vacuum closed circuit according to claim 1, wherein the flow path module is a combination of at least two pipes, and at least two pipes are matched with the connecting pipe to form at least the first row. Flow path module, second row flow path module.
The power generation auxiliary device for forming a vacuum closed circuit according to claim 2, wherein the at least two pipelines are coupled to the connecting pipe to form at least a first row flow path module and a second row flow path module.
The power generating auxiliary device for forming a vacuum closed circuit according to claim 1, wherein the agitating mechanism is combined with a fluid input portion.
The power generating auxiliary device for forming a vacuum closed circuit according to claim 2, wherein the agitating mechanism is combined with a fluid input portion.
The power generating auxiliary device for forming a vacuum closed circuit according to claim 3, wherein the agitating mechanism is combined with a fluid input portion.
The power generating auxiliary device for forming a vacuum closed circuit according to claim 4, wherein the agitating mechanism is combined with a fluid input portion.
The power generating auxiliary device for forming a vacuum closed circuit according to any one of claims 1 to 8, wherein the agitating mechanism squirts fluid inside the flow path module to allow fluid to enter from the first end of the flow path module The agitating mechanism establishes the closed loop circuit mechanism through the agitating mechanism and entering the flow path module from the second end.
The power generation auxiliary device for forming a vacuum closed circuit according to any one of claims 1 to 8, wherein the power generation module is at least divided into a first power generation module, a second power generation module, and a third power generation module;

A chamber between the first power generation module and the first end is defined as a first chamber, and a chamber between the first power generation module and the second power generation module is defined as a second chamber, a second power generation module and a third power generation module The chamber between them is defined as a third chamber;

The agitating mechanism operates to draw fluid movement in the pipeline, so that the first chamber generates a negative pressure, and the fluid pressure of the second chamber is greater than the fluid pressure in the first chamber, and the fluid passes from the second chamber to the first power generating module. Entering the first chamber, and causing the second chamber to sequentially generate a negative pressure, so that the fluid pressure of the third chamber is greater than the pressure of the second chamber, and the fluid is induced to enter the second chamber through the second power generation module. .
The power generation auxiliary device for forming a vacuum closed circuit according to any one of claims 1 to 8, wherein the flow path module is provided with a flow guiding device in a chamber before the fluid enters the power generation module.
The power generation auxiliary device for forming a vacuum closed circuit according to claim 9, wherein the flow path module is located in a chamber before the fluid enters the power generation module, and is provided with a flow guiding device.
The power generation auxiliary device for forming a vacuum closed circuit according to claim 10, wherein the flow path module is located in a chamber before the fluid enters the power generation module, and is provided with a flow guiding device.
The power generation auxiliary device for forming a vacuum closed circuit according to any one of claims 1 to 8, wherein at least a partial position of the flow path module is provided with a heat sink.
The power generation auxiliary device for forming a vacuum closed circuit according to claim 9, wherein at least a partial position of the flow path module is provided with a heat dissipation device.
The power generation auxiliary device for forming a vacuum closed circuit according to claim 10, wherein at least a partial position of the flow path module is provided with a heat dissipation device.
The power generation auxiliary device for forming a vacuum closed circuit according to claim 11, wherein at least a partial position of the flow path module is provided with a heat dissipating device.