CN209621520U - A kind of lift vertical shaft wind energy conversion system using local backward-swept blade - Google Patents

A kind of lift vertical shaft wind energy conversion system using local backward-swept blade Download PDF

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Publication number
CN209621520U
CN209621520U CN201920322822.XU CN201920322822U CN209621520U CN 209621520 U CN209621520 U CN 209621520U CN 201920322822 U CN201920322822 U CN 201920322822U CN 209621520 U CN209621520 U CN 209621520U
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China
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backward
swept
swept blade
blade
local
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CN201920322822.XU
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朱建勇
庄林学
李国文
张瑞清
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SHENYANG GUOHERUIHANG TECHNOLOGY Co.,Ltd.
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Shenyang Aerospace University
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    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02EREDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
    • Y02E10/00Energy generation through renewable energy sources
    • Y02E10/70Wind energy
    • Y02E10/74Wind turbines with rotation axis perpendicular to the wind direction

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Abstract

A kind of lift vertical shaft wind energy conversion system using local backward-swept blade, including generator, transverse arm support rod, tower bar and local backward-swept blade;Generator is vertically installed at the top of tower bar, and transverse arm support rod one end is connected with generator, and the transverse arm support rod other end is connected with local backward-swept blade;Local backward-swept blade includes prismatic blade section and backward-swept blade section, and backward-swept blade section is symmetrically distributed in prismatic blade section upper and lower ends;Transverse arm support rod is connected to the exhibition of prismatic blade section at center;The prismatic blade section of local backward-swept blade is identical with the cross-sectional shape of backward-swept blade section, is all made of aerofoil profile;In the spanwise direction of local backward-swept blade, the projected length of local backward-swept blade is set as H1, and half length of the prismatic blade section is set as H2, and H2:H1=1%~49%;The angle of sweep of backward-swept blade section is set as β, and β=1 °~89 °;The quantity of local backward-swept blade is 1~99.

Description

A kind of lift vertical shaft wind energy conversion system using local backward-swept blade
Technical field
The utility model belongs to vertical axis windmill technical field, more particularly to a kind of liter using local backward-swept blade Power type vertical axis windmill.
Background technique
Currently, energy shortages and environmental pollution are to have become the two big main problems for threatening human development, active development With one of the effective way for using new energy being then the alleviation above problem.Wind energy is as a kind of renewable free of contamination cleaning energy Source, after decades of development, wind power technology have become development and have applied most mature one of technology.Wind energy conversion system is to utilize wind The capital equipment of energy, converts wind energy into mechanical energy, and then convert mechanical energy into electric energy by generator, and wind energy conversion system is pneumatic The superiority and inferiority of characteristic directly affects the output power and generating efficiency of wind energy conversion system.Lift-type wind energy conversion system is by pneumatic equipment bladess lift The wind energy conversion system of acting, primary structure pattern include horizontal-shaft wind turbine and vertical axis H-type wind energy conversion system, lift-type wind energy conversion system revolving speed compared with Fastly, the power coefficient with higher under higher tip-speed ratio has obtained in distributed power generation field relatively broad at present Using.Vertical axis H-type wind energy conversion system is typical lift vertical shaft wind energy conversion system, is structurally characterized in that and is enclosed vertically by multiple prismatic blades It does work and then generates electricity around rotary shaft.
With the fast development of distributed power generation, small wind turbine is more next because of the advantages that its structure size is small, flexible for installation More paid attention to.However, due to the high-quality wind field that the wind field of distributed power generation generates electricity different from extensive centralization, distributed power generation Wind field environment usually there are the aerodynamic characteristics such as harmonic(-)mean wind speed, high turbulence and strong non-stationarity.In such wind field ring Under border, the power coefficient of lift-type wind energy conversion system is generally lower.
In order to improve the pneumatic efficiency of small-sized lift-type wind energy conversion system, at present generally from pneumatic equipment bladess use aerofoil profile, wind The aerodynamic configuration parameter optimization of power machine, the various aspects such as selection of generator have carried out research.However, merely from these sides Face optimizes the pneumatic efficiency for being difficult to be significantly increased existing wind energy conversion system.In order to improve the pneumatic of small-sized lift-type wind energy conversion system Efficiency, it is necessary to break through the Design of Aerodynamic Configuration of existing small wind turbine common blade.
Utility model content
In view of the problems of the existing technology, it is vertical to provide a kind of lift-type using local backward-swept blade for the utility model Axis wind energy conversion system breaches the design concept of conventional lift vertical shaft wind energy conversion system prismatic blade, the local backward-swept blade tool used There is novel aerodynamic configuration, compared with traditional prismatic blade, pneumatic efficiency and average annual energy output are obviously improved.
To achieve the goals above, the utility model adopts the following technical solution: a kind of liter using local backward-swept blade Power type vertical axis windmill, including generator, transverse arm support rod, tower bar and local backward-swept blade;The generator is vertically-mounted At the top of tower bar, transverse arm support rod one end is connected with generator, and the transverse arm support rod other end is connected with local backward-swept blade;It is described Local backward-swept blade includes prismatic blade section and backward-swept blade section, and backward-swept blade section is symmetrically distributed in prismatic blade section upper and lower ends;Institute It states transverse arm support rod and is connected to the exhibition of prismatic blade section at center.
The prismatic blade section of the part backward-swept blade is identical with the cross-sectional shape of backward-swept blade section, is all made of aerofoil profile.
In the spanwise direction of the local backward-swept blade, the projected length of local backward-swept blade is set as H1, the straight leaf Half length of segment is set as H2, and H2:H1=1%~49%.
The angle of sweep of the backward-swept blade section is set as β, and β=1 °~89 °.
The quantity of the part backward-swept blade is 1~99.
The utility model has the beneficial effects that
The lift vertical shaft wind energy conversion system using local backward-swept blade of the utility model, it is vertical to breach conventional lift-type The design concept of axis wind energy conversion system prismatic blade, the local backward-swept blade used has novel aerodynamic configuration, and traditional Prismatic blade is compared, and pneumatic efficiency and average annual energy output are obviously improved.
Detailed description of the invention
Fig. 1 is a kind of structural representation of lift vertical shaft wind energy conversion system using local backward-swept blade of the utility model Figure;
Fig. 2 is the structural schematic diagram of the local backward-swept blade of the utility model;
In figure, 1-generator, 2-transverse arm support rods, 3-tower bars, 4-local backward-swept blades, 5-prismatic blade sections, 6- Backward-swept blade section.
Specific embodiment
The utility model is described in further detail in the following with reference to the drawings and specific embodiments.
As shown in Figure 1, 2, a kind of lift vertical shaft wind energy conversion system using local backward-swept blade, including generator 1, transverse arm Support rod 2, tower bar 3 and local backward-swept blade 4;The generator 1 is vertically installed at the top of tower bar 3,2 one end of transverse arm support rod with Generator 1 is connected, and 2 other end of transverse arm support rod is connected with local backward-swept blade 4;The part backward-swept blade 4 includes prismatic blade Section 5 and backward-swept blade section 6, backward-swept blade section 6 are symmetrically distributed in 5 upper and lower ends of prismatic blade section;The transverse arm support rod 2 is connected to The exhibition of prismatic blade section 5 is at center.
The prismatic blade section 5 of the part backward-swept blade 4 is identical with the cross-sectional shape of backward-swept blade section 6, is all made of NACA0015 aerofoil profile.
In the spanwise direction of the local backward-swept blade 4, the projected length of local backward-swept blade 4 is set as H1, described straight Half length of blade sections 5 is set as H2, and H2:H1=36%.
The angle of sweep of the backward-swept blade section 6 is set as β, and β=45 °.
The quantity of the part backward-swept blade 4 is 3.
The pneumatic efficiency of wind energy conversion system can be evaluated by power coefficient with the change curve of tip-speed ratio, In, the calculation formula of power coefficient is Cp=2PM/ρAV3, the calculation formula of tip-speed ratio is λ=wR/V, in formula, PM=2 π NM/60, CPFor power coefficient, PMFor wind wheel mechanical output, ρ is atmospheric density, and A is swept area of rotor, and V is incoming flow wind Speed, λ are tip-speed ratio, and w is that wind wheel rotates angle speed, and R is wind wheel radius of turn, and n is wind speed round, and M is rotor shaft torque.
It, can be before wind energy conversion system swept area be constant when lift vertical shaft wind energy conversion system is using local backward-swept blade 4 It puts and increases length of blade and area, so that the acting area of pneumatic equipment bladess increases;In wind energy conversion system rotary course, sweepback leaf The linear velocity of segment 6 can resolve into two parts, and first part is the tangential speed along leaf chord length, and second part is Along blade open up to exhibition Xiang Sudu, it is therein to open up the boundary layer flow and blade point that blade surface is effectively controlled to speed The flow losses at end, to improve the pneumatic efficiency of wind energy conversion system;In wind energy conversion system rotary course, prismatic blade section 5 is without carrying out speed Degree decomposes, and can still keep biggish tangential speed, and then keep stronger acting ability.
Scheme in embodiment is not the scope of patent protection to limit the utility model, all without departing from the utility model Carried out by equivalence enforcement or change, be both contained in the scope of the patents of this case.

Claims (5)

1. a kind of lift vertical shaft wind energy conversion system using local backward-swept blade, it is characterised in that: supported including generator, transverse arm Bar, tower bar and local backward-swept blade;The generator is vertically installed at the top of tower bar, transverse arm support rod one end and generator phase Even, the transverse arm support rod other end is connected with local backward-swept blade;The part backward-swept blade includes prismatic blade section and backward-swept blade Section, backward-swept blade section are symmetrically distributed in prismatic blade section upper and lower ends;The transverse arm support rod is connected to the Zhan Xiangzhong of prismatic blade section At the heart.
2. a kind of lift vertical shaft wind energy conversion system using local backward-swept blade according to claim 1, it is characterised in that: The prismatic blade section of the part backward-swept blade is identical with the cross-sectional shape of backward-swept blade section, is all made of aerofoil profile.
3. a kind of lift vertical shaft wind energy conversion system using local backward-swept blade according to claim 1, it is characterised in that: In the spanwise direction of the local backward-swept blade, the projected length of local backward-swept blade is set as H1, and the half of the prismatic blade section Length is set as H2, and H2:H1=1%~49%.
4. a kind of lift vertical shaft wind energy conversion system using local backward-swept blade according to claim 1, it is characterised in that: The angle of sweep of the backward-swept blade section is set as β, and β=1 °~89 °.
5. a kind of lift vertical shaft wind energy conversion system using local backward-swept blade according to claim 1, it is characterised in that: The quantity of the part backward-swept blade is 1~99.
CN201920322822.XU 2019-03-14 2019-03-14 A kind of lift vertical shaft wind energy conversion system using local backward-swept blade Active CN209621520U (en)

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CN201920322822.XU CN209621520U (en) 2019-03-14 2019-03-14 A kind of lift vertical shaft wind energy conversion system using local backward-swept blade

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Application Number Priority Date Filing Date Title
CN201920322822.XU CN209621520U (en) 2019-03-14 2019-03-14 A kind of lift vertical shaft wind energy conversion system using local backward-swept blade

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Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN109812381A (en) * 2019-03-14 2019-05-28 沈阳航空航天大学 A kind of lift vertical shaft wind energy conversion system using local backward-swept blade

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN109812381A (en) * 2019-03-14 2019-05-28 沈阳航空航天大学 A kind of lift vertical shaft wind energy conversion system using local backward-swept blade

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Effective date of registration: 20210722

Address after: 110036 91-z11, Kaifa 25th Road, Shenyang Economic and Technological Development Zone, Liaoning Province

Patentee after: SHENYANG GUOHERUIHANG TECHNOLOGY Co.,Ltd.

Address before: 110136, Liaoning, Shenyang moral and Economic Development Zone, No. 37 South Avenue moral

Patentee before: SHENYANG AEROSPACE University