CN201621018U - Super wind tower - Google Patents

Super wind tower Download PDF

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Publication number
CN201621018U
CN201621018U CN 201020131145 CN201020131145U CN201621018U CN 201621018 U CN201621018 U CN 201621018U CN 201020131145 CN201020131145 CN 201020131145 CN 201020131145 U CN201020131145 U CN 201020131145U CN 201621018 U CN201621018 U CN 201621018U
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CN
China
Prior art keywords
wind
cantilever
vertical pivot
cylinder
rotary table
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Expired - Fee Related
Application number
CN 201020131145
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Chinese (zh)
Inventor
张智坤
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Individual
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Individual
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Priority to CN 201020131145 priority Critical patent/CN201621018U/en
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Publication of CN201621018U publication Critical patent/CN201621018U/en
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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

Abstract

The utility model relates to a super wind tower comprising a tower frame and a plurality layers of windsurfings, wherein each layer of windsurfings comprises a left wind-separating plate, a right wind-separating plate, a left wind wing, a right wind wing, an upper rotating disc, a lower rotating disc and a framework, wherein the framework is triangular and comprises a top frame, a bottom frame, a left side beam and a right side beam; the left wind wing comprises a left front vertical shaft, a left rear vertical shaft, a left front roller, a left rear roller, a left upper cantilever, a left lower cantilever, a left wind-blocking belt and a left generator; the right wind wing comprises a right front vertical shaft, a right rear vertical shaft, a right front roller, a right rear roller, a right upper cantilever, a right lower cantilever, a right wind-blocking belt and a right generator; on the different elevations of the tower frame, the position, corresponding to the each layer of windsurfings, is provided with an upper guide rail, and the position thereof, corresponding to the lower rotating disc of each layer of windsurfings, is provided with a lower guide rail; the upper rotating discs of each layer of windsurfings are connected with the corresponding upper guide rail on the tower frame by the upper roller; and the lower rotating disc of each layer of windsurfings is connected with the corresponding lower guider rail on the tower frame by the lower roller. The super wind tower has very high weight bearing force and anti-cutting force, large wind-blocking area, large effective wind-bearing area and high wind-energy utilization ratio.

Description

Super wind tower
Technical field
The utility model relates to wind power plant.
Background technique
In order to tackle the situation of energy supply growing tension, countries in the world are all seeking to substitute fossil energy with renewable energy sources, and wherein wind-powered electricity generation is competitive, a most promising renewable energy technologies.
At present, the most representative in the known wind generating unit is wind turbine generator, wind turbine generator is installed on the pylon, the front end of generator input shaft is equipped with impeller, input shaft is in substantially horizontal, and the plane at impeller place is vertical facade, and impeller has three blades, blade facings the wind and rotates, the drive input shaft rotates, and for generator provides power, blade is an elongated shape, its wind-exposuring area is little, poor to the adaptive capacity that wind direction changes, in the unsettled area of wind direction, can't use, so it is high that existing wind turbine generator requires the installation site, application area is narrow.
Because impeller has only three blades, blade is an elongated shape, and blowing area is little, and utilization ratio of wind energy is low, and output power is low, has influenced generated energy.Because single-machine capacity is low, extensive generating needs tens even hundreds of platform are installed, and the construction land area is big.
For this reason, I successively researched and developed two generation wind power plant: " taking turns the wind-driven generator hanger " and " universal wind tower ", and applied for patent more, more first generation wind power plant " is taken turns the wind-driven generator hanger " and is had very high load-bearing and anti-shearing force, but it is little to block the wind area, and wind energy utilization is low.
Second generation wind power plant " universal wind tower " can lamination assembling, it is high to reach rice up to a hundred, it is big to block the wind area, but impeller always has one side to be in lee face, thereby effectively blowing area (windward side and lee face poor) is little, wind energy utilization is low.
The model utility content
For addressing the above problem, the purpose of this utility model provides a kind of super wind tower, this super wind tower is the third generation new product of researching and developing after my first, second generation wind power plant patent application, have very high bearing capacity and anti-shearing force, it is big to block the wind area, and effectively blowing area is big, can assemble by lamination, it is high to reach rice up to a hundred, the wind energy utilization height.
For achieving the above object, the utility model is by the following technical solutions:
A kind of super wind tower, comprise pylon and the multilayer sail that is arranged on the pylon different level, it is characterized in that: described each layer sail structure is identical, every layer of sail all is by parting aerofoil on the left side, part aerofoil on the right side, Zuo Fengyi, the right wind wing, top rotary table, lower rotary table and skeleton constitute, skeleton is a prismatic, by the top frame, underframe, left side beam, right side beam is formed, left side beam is connected across the top frame, the left side of underframe, right side beam is connected across the top frame, the right side of underframe, parting aerofoil on the left side is installed on the left side beam, parting aerofoil on the right side is installed on the right side beam, top rotary table is installed in the inside of top frame, lower rotary table is installed in the inside of underframe, the top frame, the left back end of underframe is respectively arranged with upper left bearing support and lower-left bearing support, the top frame, the right rear end of underframe is respectively arranged with upper right bearing support and bottom right bearing support, Zuo Fengyi is by left front vertical pivot, left back vertical pivot, left front cylinder, left back cylinder, upper left cantilever, the lower-left cantilever, the wind band is blocked on a left side and left generator is formed, upper left cantilever, the lower-left cantilever is integral by left connecting rod is affixed, left back vertical pivot is fixed in upper left cantilever, the rear portion of lower-left cantilever, on the left front vertical pivot, following two ends are supported by the bearing in upper left bearing support and the lower-left bearing support respectively, upper left cantilever, the front end of lower-left cantilever is connected on the upper and lower of left front vertical pivot respectively by shaft hole sleeve, left back cylinder by bearing hinge joint on left back vertical pivot, left front cylinder is welded on the left front vertical pivot by left quarter butt, the wind band is blocked around left front cylinder in a left side, between the left back cylinder, left side generator is fixed on the frame of top by left socle, the input shaft and the left front vertical shaft of left side generator are affixed, a left side is blocked the lobus sinister sheet is housed on the wind band, the right wind wing is by right front vertical pivot, right back vertical pivot, right front cylinder, right back cylinder, upper right cantilever, the bottom right cantilever, the wind band is blocked on the right side and right generator is formed, upper right cantilever, the bottom right cantilever is integral by right connecting rod is affixed, on the right back vertical pivot, following two ends are fixed in upper right cantilever respectively, the rear portion of bottom right cantilever, on the right front vertical pivot, following two ends are supported by the bearing in upper right bearing support and the bottom right bearing support respectively, upper right cantilever, the front end of bottom right cantilever is connected on the upper and lower of right front vertical pivot respectively by shaft hole sleeve, right back cylinder by bearing hinge joint on right back vertical pivot, right front cylinder is welded on the right front vertical pivot by right quarter butt, the wind band is blocked around right front cylinder in the right side, between the right back cylinder, right generator is fixed on the frame of top by right support, the input shaft and the right front vertical shaft of right generator are affixed, the right side is blocked the lobus dexter sheet is housed on the wind band, on the different level of described pylon, the position corresponding with each layer sail top rotary table is provided with upper rail, the position corresponding with each layer sail lower rotary table is provided with lower rail, the top rotary table of each layer sail connects by upper rail corresponding on upper roller and the pylon, and the lower rotary table of each layer sail is by corresponding lower rail connection on bottom roller and the pylon.
Because adopt above technological scheme: the utility model has following positive beneficial effect:
One, every layer of sail all is provided with the left and right wind wing, can seek wind direction certainly, behind the change of the wind, sail can be adjusted the azimythal angle automatically, and what make the left and right wind wing blocks the wind band always in face of wind direction, and it is big to block the wind area, do not have lee face, effectively blowing area is big, to greatest extent capturing wind energy, when wind is to the blade that blocks the wind band, blade produces moment of torsion, makes to block the wind band around the cylinder rotation, and cylinder drives the vertical pivot rotation, vertical pivot drives the main axis rotation of generator, thereby produces electric energy.
Two, every layer of sail all is provided with upper and lower roller, and bottom roller is vertically installed, and very big bearing capacity is arranged, and upper roller is laterally installed, and very big anti-shearing force is arranged, and runs into very big crosswind and also can keep balance.
Run well, compare with existing blower fan, its load-bearing anti-shearing force can improve 2-3 doubly.
Three, sail adopts multilayer to pile up folded arranged in form, can increase the blowing area of vertical plane, forms bigger wind sail type generating tower, and floor space is little, the wind energy utilization height.
Description of drawings
Fig. 1 is the utility model one embodiment's a structural representation.
Fig. 2 is the structural representation behind each layer sail removal split-wind plate among Fig. 1.
Fig. 3 is the structural representation of pylon among Fig. 1.
Fig. 4 is the structural representation of sail.
Fig. 5 is the structural representation behind the sail removal split-wind plate among Fig. 4.
Fig. 6 is the structural representation of skeleton.
Fig. 7 is the structural representation of cantilever.
Fig. 8 is the structural representation of the left wind wing.
Fig. 9 is the linkage structure schematic representation of top rotary table and upper rail.
Figure 10 is the linkage structure schematic representation of lower rotary table and lower rail.
Embodiment
Number in the figure
1 sail, 2 sails, 3 sails
4 part aerofoil 5 on the left side parts the aerofoil 6 left wind wings on the right side
The 7 right wind wing 8 top rotary tables 9 lower rotary tables
10 pylons, 11 skeletons, 12 top frames
13 underframes, 14 left side beams, 15 right side beams
16 upper left bearing support 17 lower-left bearing supports 18 upper right bearing supports
19 bottom right bearing supports, 20 bearings
21 left front vertical pivot 22 left back vertical pivot 23 left front cylinders
24 left back cylinder 25 upper left cantilever 26 lower-left cantilevers
Wind band 28 left generator 29 left connecting rods are blocked on 27 left sides
30 bearings, 31 upper rails, 32 upper rails
33 upper rails, 34 lower rails, 35 lower rails
36 lower rails, 37 lobus sinister sheets, 38 upper rollers
39 bottom rollers, 40 left socles, 41 left quarter butts
42 bearings, 43 bearings
Please refer to Fig. 1, Fig. 2, Fig. 3, the utility model is a kind of super wind tower, comprises that pylon 10 is identical with 1,2,3, three layers of sail 1,2,3 structure of three layers of sail that are arranged on pylon 10 different levels, is that example illustrates its structure with second layer sail 2 below.
Please refer to Fig. 4, Fig. 5, Fig. 6, sail 2 be by part aerofoil 4 on the left side, part aerofoil 5 on the right side, the left wind wing 6, the right wind wing 7, top rotary table 8, lower rotary table 9 and skeleton 11 constitute, skeleton 11 is a prismatic, form by top frame 12, underframe 13, left side beam 14, right side beam 15, left side beam 14 is connected across the left side of top frame 12, underframe 13, and right side beam 15 is connected across the right side of top frame 12, underframe 13.
Part aerofoil 4 on the left side and be installed on the left side beam 14, part aerofoil 5 on the right side and be installed on the right side beam 15, top rotary table 8 is installed in the inside of top frame 12, and lower rotary table 9 is installed in the inside of underframe 13; Please refer to Fig. 6, the bight of top frame 12, underframe 13 left back ends is respectively arranged with upper left bearing support 16 and lower-left bearing support 17, and the bight of top frame 12, underframe 13 right rear ends is respectively arranged with upper right bearing support 18 and bottom right bearing support 19,
The left side wind wing 6, the right wind wing 7 structures are identical, are that example illustrates its concrete structure with the left wind wing 6 below.
Please refer to Fig. 7, Fig. 8, the left side wind wing 6 is by left front vertical pivot 21, left back vertical pivot 22, left front cylinder 23, left back cylinder 24, upper left cantilever 25, lower-left cantilever 26, wind band 27 is blocked on a left side and left generator 28 is formed, upper left cantilever 25, lower-left cantilever 26 is by left connecting rod 29 affixed being integral, left back vertical pivot 22 is fixed in upper left cantilever 25, the rear portion of lower-left cantilever 26, on the left front vertical pivot 21, following two ends are respectively by the bearing 42 in upper left bearing support 16 and the lower- left bearing support 17,43 supportings, upper left cantilever 25, the front end of lower-left cantilever 26 is connected on the upper and lower of left front vertical pivot 21 respectively by shaft hole sleeve, left back cylinder 24 is by bearing 20,30 are articulated on the left back vertical pivot 22, left front cylinder 23 is welded on the left front vertical pivot 21 by left quarter butt 41, a left side is blocked wind band 27 and is looped around left front cylinder 23, between the left back cylinder 24, a left side is blocked lobus sinister sheet 37 is housed on the wind band 27, left side generator 28 is fixed on the top frame 12 by left socle 40, and the input shaft of left generator 28 and left front vertical shaft 21 are affixed.
Please refer to Fig. 3, on the different level of pylon 10, the position corresponding with the top rotary table 8 of three layers of sail 1,2,3 is provided with upper rail 31,32,33, and on the different level of pylon 10, the position corresponding with the lower rotary table 9 of three layers of sail 1,2,3 is provided with lower rail 34,35,36.
Please refer to Fig. 9, the top rotary table 8 of each layer sail 1,2,3 is by corresponding upper rail connection on upper roller 38 and the pylon 10, please refer to Figure 10, the lower rotary table of each layer sail 1,2,39 by bottom roller 39 respectively with pylon 10 on corresponding lower rail 34,35,36 connections.
When wind is blocked on the lobus sinister sheet 37 of wind band 27 to a left side, lobus sinister sheet 37 produces moment of torsion, makes a left side block wind band 27 around left front cylinder 23,24 rotations of left back cylinder, and left front cylinder 23 drives left front vertical pivot 21 rotations, left front vertical pivot 21 drives the main axis rotation of left generator 28, thereby produces electric energy.
Each layer sail 1,2,3 all is provided with the left and right wind wing 6,7, can seek wind direction certainly, behind the change of the wind, sail 1,2,3 can be adjusted the azimythal angle automatically, what make the left and right wind wing 6,7 blocks the wind band always in face of wind direction, and it is big to block the wind area, does not have lee face, effectively blowing area is big, to greatest extent capturing wind energy.
Every layer of sail 1,2,3 all is provided with upper and lower roller 38,39, bottom roller 39 is vertically installed, very big bearing capacity is arranged, upper roller 38 is laterally installed, and very big anti-shearing force is arranged, and runs into very big crosswind and also can keep balance, sail is run well, compare with existing blower fan, its load-bearing anti-shearing force can improve 2-3 doubly.
Sail 1,2,3 adopts multilayer to pile up folded arranged in form, can increase the blowing area of vertical plane, forms bigger wind sail type generating tower, and floor space is little, the wind energy utilization height.

Claims (1)

1. super wind tower, comprise pylon and the multilayer sail that is arranged on the pylon different level, it is characterized in that: described each layer sail structure is identical, every layer of sail all is by parting aerofoil on the left side, part aerofoil on the right side, Zuo Fengyi, the right wind wing, top rotary table, lower rotary table and skeleton constitute, skeleton is a prismatic, by the top frame, underframe, left side beam, right side beam is formed, left side beam is connected across the top frame, the left side of underframe, right side beam is connected across the top frame, the right side of underframe, parting aerofoil on the left side is installed on the left side beam, parting aerofoil on the right side is installed on the right side beam, top rotary table is installed in the inside of top frame, lower rotary table is installed in the inside of underframe, the top frame, the left back end of underframe is respectively arranged with upper left bearing support and lower-left bearing support, the top frame, the right rear end of underframe is respectively arranged with upper right bearing support and bottom right bearing support, Zuo Fengyi is by left front vertical pivot, left back vertical pivot, left front cylinder, left back cylinder, upper left cantilever, the lower-left cantilever, the wind band is blocked on a left side and left generator is formed, upper left cantilever, the lower-left cantilever is integral by left connecting rod is affixed, left back vertical pivot is fixed in upper left cantilever, the rear portion of lower-left cantilever, on the left front vertical pivot, following two ends are supported by the bearing in upper left bearing support and the lower-left bearing support respectively, upper left cantilever, the front end of lower-left cantilever is connected on the upper and lower of left front vertical pivot respectively by shaft hole sleeve, left back cylinder by bearing hinge joint on left back vertical pivot, left front cylinder is welded on the left front vertical pivot by left quarter butt, the wind band is blocked around left front cylinder in a left side, between the left back cylinder, left side generator is fixed on the frame of top by left socle, the input shaft and the left front vertical shaft of left side generator are affixed, a left side is blocked the lobus sinister sheet is housed on the wind band, the right wind wing is by right front vertical pivot, right back vertical pivot, right front cylinder, right back cylinder, upper right cantilever, the bottom right cantilever, the wind band is blocked on the right side and right generator is formed, upper right cantilever, the bottom right cantilever is integral by right connecting rod is affixed, on the right back vertical pivot, following two ends are fixed in upper right cantilever respectively, the rear portion of bottom right cantilever, on the right front vertical pivot, following two ends are supported by the bearing in upper right bearing support and the bottom right bearing support respectively, upper right cantilever, the front end of bottom right cantilever is connected on the upper and lower of right front vertical pivot respectively by shaft hole sleeve, right back cylinder by bearing hinge joint on right back vertical pivot, right front cylinder is welded on the right front vertical pivot by right quarter butt, the wind band is blocked around right front cylinder in the right side, between the right back cylinder, right generator is fixed on the frame of top by right support, the input shaft and the right front vertical shaft of right generator are affixed, the right side is blocked the lobus dexter sheet is housed on the wind band, on the different level of described pylon, the position corresponding with each layer sail top rotary table is provided with upper rail, the position corresponding with each layer sail lower rotary table is provided with lower rail, the top rotary table of each layer sail connects by upper rail corresponding on upper roller and the pylon, and the lower rotary table of each layer sail is by corresponding lower rail connection on bottom roller and the pylon.
CN 201020131145 2010-03-15 2010-03-15 Super wind tower Expired - Fee Related CN201621018U (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
CN 201020131145 CN201621018U (en) 2010-03-15 2010-03-15 Super wind tower

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
CN 201020131145 CN201621018U (en) 2010-03-15 2010-03-15 Super wind tower

Publications (1)

Publication Number Publication Date
CN201621018U true CN201621018U (en) 2010-11-03

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Family Applications (1)

Application Number Title Priority Date Filing Date
CN 201020131145 Expired - Fee Related CN201621018U (en) 2010-03-15 2010-03-15 Super wind tower

Country Status (1)

Country Link
CN (1) CN201621018U (en)

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN102226444A (en) * 2011-04-29 2011-10-26 高克君 Track sliding-rotating bearing and framework hollow shaft

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN102226444A (en) * 2011-04-29 2011-10-26 高克君 Track sliding-rotating bearing and framework hollow shaft

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Legal Events

Date Code Title Description
C14 Grant of patent or utility model
GR01 Patent grant
C17 Cessation of patent right
CF01 Termination of patent right due to non-payment of annual fee

Granted publication date: 20101103

Termination date: 20130315