CN107013411A - String type vertical shaft wind power generating machine - Google Patents
String type vertical shaft wind power generating machine Download PDFInfo
- Publication number
- CN107013411A CN107013411A CN201710385250.5A CN201710385250A CN107013411A CN 107013411 A CN107013411 A CN 107013411A CN 201710385250 A CN201710385250 A CN 201710385250A CN 107013411 A CN107013411 A CN 107013411A
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- China
- Prior art keywords
- wind
- vertical axis
- vertical
- rotating shaft
- power generating
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- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
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Classifications
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F03—MACHINES OR ENGINES FOR LIQUIDS; WIND, SPRING, OR WEIGHT MOTORS; PRODUCING MECHANICAL POWER OR A REACTIVE PROPULSIVE THRUST, NOT OTHERWISE PROVIDED FOR
- F03D—WIND MOTORS
- F03D3/00—Wind motors with rotation axis substantially perpendicular to the air flow entering the rotor
- F03D3/02—Wind motors with rotation axis substantially perpendicular to the air flow entering the rotor having a plurality of rotors
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F05—INDEXING SCHEMES RELATING TO ENGINES OR PUMPS IN VARIOUS SUBCLASSES OF CLASSES F01-F04
- F05B—INDEXING SCHEME RELATING TO WIND, SPRING, WEIGHT, INERTIA OR LIKE MOTORS, TO MACHINES OR ENGINES FOR LIQUIDS COVERED BY SUBCLASSES F03B, F03D AND F03G
- F05B2240/00—Components
- F05B2240/90—Mounting on supporting structures or systems
- F05B2240/91—Mounting on supporting structures or systems on a stationary structure
- F05B2240/912—Mounting on supporting structures or systems on a stationary structure on a tower
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- Y—GENERAL 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
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02B—CLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO BUILDINGS, e.g. HOUSING, HOUSE APPLIANCES OR RELATED END-USER APPLICATIONS
- Y02B10/00—Integration of renewable energy sources in buildings
- Y02B10/30—Wind power
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- Y—GENERAL 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
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02E—REDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
- Y02E10/00—Energy generation through renewable energy sources
- Y02E10/70—Wind energy
- Y02E10/728—Onshore wind turbines
-
- Y—GENERAL 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
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02E—REDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
- Y02E10/00—Energy generation through renewable energy sources
- Y02E10/70—Wind energy
- Y02E10/74—Wind turbines with rotation axis perpendicular to the wind direction
Abstract
The string type vertical shaft wind power generating machine of the application is by the way that vertical axis rotor in the vertical direction is stringed together so that a kind of high-rise or Super High wind-power electricity generation that turns into of vertical axis aerogenerator is built, and the utilization rate for high aerial wind energy is higher.Simultaneously by multiple vertical axis rotors into string data connection, the size of vertical axis rotor is reduced on the higher wind-driven generator of height, equivalent to it is in multiple vertical axis rotors to split a larger vertical axis rotor, reduces the installation difficulty and difficulty of processing of vertical axis rotor.Simultaneously because the size of monomer vertical axis rotor reduces, the wind oar equal strength for vertical axis rotor is also reduced accordingly.
Description
Technical field
The application is related to wind power generation field, in particular to string type vertical shaft wind power generating machine.
Background technology
Wind-driven generator is that wind energy is converted into mechanical energy, and mechanical energy is converted to the power equipment of electric energy.It is big-and-middle-sized at present
Wind-powered electricity generation mainly uses horizontal-shaft wind turbine, belongs to lift-type wind energy conversion system, has the advantages that rotating speed is high, wind utilization rate is higher.At present
The wind-driven generator main flow wind-driven generator for putting into commercial operation is substantially horizontal axis wind-driven generator.
The support of wind-driven generator uses vertical upright tower, with the continuous increasing of horizontal axis wind-driven generator capacity
Greatly, the capacity of current main flow wind-driven generator is up to 2 megawatts -3.5 megawatts, and the weight of the overall cabin of corresponding generator is
Up to 70-100 tons, cabin altitude also reaches 100 meters or so.The making of equipment, transport, installation cost are dramatically increased, therefore level
The development of axis wind power generator has reached bottleneck period.
Rotary shaft is vertical wind-driven generator vertical axis aerogenerator.Vertical axis aerogenerator has low noise
The advantages of sound, simple maintenance.But why conventional vertical axis wind power generator is not developed in recent decades, mainly hang down
D-axis wind-driven generator has following some shortcomings.
The wind energy utilization of conventional vertical axis wind power generator is low.Because the blade of conventional vertical axis wind power generator is solid
Fixed, acting is being offset in blade promotion of the blade wind-engaging of opposite side while wind is promoted and done work in side, thus causes wind
The utilization rate of energy is not high.
The horizontal support bar of traditional H types vertical axis aerogenerator is cantilevered structure, is handed in the thrust for the wind received for direction
Become, rod member is easily tired.To overcome the shortcoming that this rigidity of vertical axis aerogenerator is poor, need to increase wind wheel support system again
The bar cross section size of system, has accordingly increased the weight of wind wheel, is restricted the wind sweeping area of wind wheel, makes conventional vertical
The unit generating capacity of axis wind power generator receives restriction.
The generator of conventional vertical axis wind power generator is a ring-type, during installation need to crane from tower (perpendicular to
The support bar on ground) top pack into support bar, therefore the height of tower can not possibly be too high, while installation difficulty is larger.Wind wheel
Installation if using overall turn, because weight is larger, it is clear that installation has a larger difficulty, and if using dissipating
Dress, it is envisaged that in the air can be more difficult in height.
Apply for content
In view of this, the purpose of the application be in order to overcome it is of the prior art it is not enough there is provided a kind of high-rise or Super High,
The small string type vertical shaft wind power generating machine of installation, difficulty of processing.
In order to solve the above technical problems, the technical scheme that the application is used is:
String type vertical shaft wind power generating machine, including vertical axis rotor and generator, the vertical axis rotor include and institute
The connected wind wheel rotating shaft of generator, in addition to vertical rack are stated, vertical axis rotor string described at least two is located at the vertical branch
Rotated on frame and relative to the vertical rack, each vertical axis rotor is connected with an institute for being fixedly arranged on the vertical rack
State generator.
In the exemplary embodiment, the vertical rack is tower;
The wind wheel rotating shaft is cylindrical in shape and is rotatably arranged in the outer wall of the tower, and the inner side of the wind wheel rotating shaft is permanent magnetism
Ring;
Be additionally provided with the stator of the generator between the outer wall of the tower and the permanent-magnetic clamp, the stator with it is described forever
There is air gap between magnet ring.
In the exemplary embodiment, the vertical rack is tower;
The wind wheel rotating shaft is cylindrical in shape and is rotatably arranged in the outer wall of the tower;
The rotor relative stator of the generator is rotated;
The rotor is connected with the wind wheel rotating shaft by gearbox, in the wind wheel rotating shaft and the rotor with it is described
Gearbox is driven by gear pair.
In the exemplary embodiment, the tower uses cast-in-place concrete filled steel tube lattice.
In the exemplary embodiment, the top of the tower is provided with the truss of a horizontal positioned, and the two ends of the truss exist
Stretched out in the tower.
In the exemplary embodiment, the vertical rack is the caged framework that in the vertical direction is stacked, each cage
Vertical axis rotor described in one is rotatably provided with formula framework and generator described in one is installed with.
In the exemplary embodiment, the vertical axis rotor includes support arm, the rotating shaft of wind oar and wind oar;
Being connected in the wind wheel rotating shaft radially of support arm described at least three, the wind oar passes through the wind oar
It is connected on the support arm axis of rotation.
In the exemplary embodiment, the vertical axis rotor also includes wind direction sensing device and drive device;
The wind direction sensing device is used to sense wind direction;
Drive device driving be located at the wind oar of half cycle windward all the time perpendicular to wind direction level point to;
Drive device driving positioned at contrary wind half cycle the wind oar all the time parallel to wind direction level point to.
In the exemplary embodiment, support bar, support bar structure in the plane are provided between the adjacent support arm
Into regular polygon.
In the exemplary embodiment, the vertical axis rotor includes also including wind wheel hub;
The wind wheel hub includes axle sleeve, spoke and hub circle, and the axle sleeve is sheathed in the wind wheel rotating shaft, the spoke one
End is connected with wind wheel rotating shaft, and the other end is connected with hub circle;
At least three support arm in the same direction with the radial direction of the hub circle is evenly equipped with the outside of the hub circle, the wind oar leads to
It is connected on the support arm with crossing the wind oar axis of rotation.
Compared with prior art, its remarkable advantage is the application:
The string type vertical shaft wind power generating machine of the application is by the way that vertical axis rotor in the vertical direction is stringed together so that hang down
D-axis wind-driven generator turns into a kind of high-rise or Super High wind-power electricity generation building, for high aerial wind energy utilization rate more
It is high.Multiple vertical axis rotors are reduced into vertical axis rotor into the connection of string data on the higher wind-driven generator of height simultaneously
Size, equivalent to being in multiple vertical axis rotors by a larger vertical axis rotor segmentation, reduce the peace of vertical axis rotor
Fill difficulty and difficulty of processing.Simultaneously because the size of monomer vertical axis rotor reduces, for the wind oar equal strength of vertical axis rotor
Also corresponding reduction.
For enable the above-mentioned purpose of the application, feature and advantage become apparent from understandable, preferred embodiment cited below particularly, and match somebody with somebody
Appended accompanying drawing is closed, is described below in detail.
Brief description of the drawings
, below will be attached to what is used required in embodiment in order to illustrate more clearly of the technical scheme of the embodiment of the present application
Figure is briefly described, it will be appreciated that the following drawings illustrate only some embodiments of the application, therefore is not construed as pair
The restriction of scope, for those of ordinary skill in the art, on the premise of not paying creative work, can also be according to this
A little accompanying drawings obtain other related accompanying drawings.
Fig. 1 shows that the string type vertical shaft wind power generating machine structure for the wind-driven generator that the embodiment of the present application 1 is provided is shown
It is intended to;
Fig. 2 shows the structural representation of the tower for the string type vertical shaft wind power generating machine that the embodiment of the present application 1 is provided;
Fig. 3 shows the front view for the string type vertical shaft wind power generating machine that the embodiment of the present application 1 is provided;
Fig. 4 shows the part section structural representation for the string type vertical shaft wind power generating machine that the embodiment of the present application 1 is provided
Figure;
Fig. 5 shows the top view of the tower for the string type vertical shaft wind power generating machine that the embodiment of the present application 1 is provided;
Fig. 6 shows the top view for the string type vertical shaft wind power generating machine that the embodiment of the present application 1 is provided;
Fig. 7 shows the vertical view of the vertical axis rotor for the string type vertical shaft wind power generating machine that the embodiment of the present application is provided
Figure;
Fig. 8 shows the main view of the vertical axis rotor for the string type vertical shaft wind power generating machine that the embodiment of the present application is provided
Figure;
Fig. 9 shows the part of the vertical axis rotor for the string type vertical shaft wind power generating machine that the embodiment of the present application 1 is provided
Mplifying structure schematic diagram;
Figure 10 shows the top view of the tower for the string type vertical shaft wind power generating machine that the embodiment of the present application 2 is provided;
Figure 11 shows the axle geodesic structure schematic diagram for the string type vertical shaft wind power generating machine that the embodiment of the present application 3 is provided;
Figure 12 shows that the axle of the caged framework for the string type vertical shaft wind power generating machine that the embodiment of the present application 3 is provided surveys knot
Structure schematic diagram.
Icon:1- string type vertical shaft wind power generating machines;10- vertical axis rotors;101- wind wheel rotating shafts;102- support arms;
103- wind oar rotating shafts;104- wind oars;105- vertical support bars;106- horizontal support bars;107- drive devices;108- wind wheel hubs;
1081- axle sleeves;1082- spokes;1083- hub circles;20- generators;201- stators;202- rotors;30- towers;301- steel platforms;
The vertical elevators of 302-;303- truss;40- gearboxes;50- caged frameworks;501- cruciform bracings;502- upright of frame.
Embodiment
Hereinafter, the various embodiments of the disclosure will be described more fully with reference to accompanying drawing.The disclosure can have various realities
Example is applied, and can adjust and change wherein.Therefore, will in more detail it be retouched with reference to the specific embodiment being shown in the drawings
State the disclosure.It should be understood, however, that:In the absence of the meaning that the various embodiments of the disclosure are limited to specific embodiment disclosed herein
Figure, but the disclosure should be interpreted as covering all adjustment in the spirit and scope for the various embodiments for falling into the disclosure, etc.
Jljl and/or alternative.Description taken together with the accompanying drawings, the same element of same reference numerals.
Hereinafter, the term " comprising " that can be used in the various embodiments of the disclosure or " may include " indicate disclosed
Function, operation or the presence of element, and do not limit the increase of one or more functions, operation or element.In addition, such as existing
Used in the various embodiments of the disclosure, term " comprising ", " having " and its cognate are meant only to represent special characteristic, number
Word, step, operation, element, the combination of component or foregoing item, and be understood not to exclude first one or more other
Feature, numeral, step, operation, element, the presence of the combination of component or foregoing item or increase one or more features, numeral,
Step, operation, element, the possibility of the combination of component or foregoing item.
In the various embodiments of the disclosure, statement "or" or " in A or/and B at least one " include what is listed file names with
Any combinations of word or all combinations." A or B " or " in A or/and B at least one " may include A, may include for example, statement
B may include A and B both.
The statement (" first ", " second " etc.) used in the various embodiments of the disclosure can be modified to be implemented various
Various element in example, but corresponding element can not be limited.For example, presented above be not intended to limit the suitable of the element
Sequence and/or importance.The purpose presented above for being only used for differentiating an element and other elements.For example, the first user fills
Put and indicate different user device with second user device, although the two is all user's set.For example, not departing from each of the disclosure
In the case of the scope for planting embodiment, the first element is referred to alternatively as the second element, similarly, and the second element is also referred to as first
Element.
It should be noted that:, can be by the first composition member if an element ' attach ' to another element by description
Part is directly connected to the second element, and " connection " the 3rd can be constituted between the first element and the second element
Element.On the contrary, when an element " being directly connected to " is arrived into another element, it will be appreciated that be in the first element
And second the 3rd element is not present between element.
The term used in the various embodiments of the disclosure is only used for describing the purpose of specific embodiment and not anticipated
In the various embodiments of the limitation disclosure.As used herein, singulative is intended to also include plural form, unless context is clear
Chu it is indicated otherwise.Unless otherwise defined, all terms (including the technical term and scientific terminology) tool being otherwise used herein
There is the implication identical implication that the various embodiment one skilled in the art with the disclosure are generally understood that.The term
(term such as limited in the dictionary typically used) is to be interpreted as having and the situational meaning in correlative technology field
Identical implication and it will be not construed as with Utopian implication or excessively formal implication, unless in the various of the disclosure
It is clearly defined in embodiment.
Below in conjunction with the accompanying drawings, the embodiment to the application elaborates.
Embodiment 1
As shown in figure 1, the present embodiment provides a kind of string type vertical shaft wind power generating machine 1, it include vertical axis rotor 10 with
And generator 20.Vertical axis rotor 10 includes the wind wheel rotating shaft 101 being connected with generator 20.String type vertical shaft wind power generating machine 1
Also include vertical rack, at least two vertical axis rotors 10 string is located on vertical rack and opposed vertical holder pivots, each to hang down
D-axis wind wheel 10 is connected with a generator 20 for being fixedly arranged on vertical rack.
It is above-mentioned, by the way that the in the vertical direction of vertical axis rotor 10 is stringed together so that vertical axis aerogenerator 20 into
For a kind of high-rise or Super High wind-power electricity generation building, the utilization rate for high aerial wind energy is higher.Simultaneously by multiple vertical axises
Wind wheel 10 reduces the size of vertical axis rotor 10 into the connection of string data on the higher wind-driven generator 20 of height, equivalent to,
One larger vertical axis rotor 10 is split in multiple vertical axis rotors 10, reduce vertical axis rotor 10 installation difficulty and
Difficulty of processing.Simultaneously because the size of monomer vertical axis rotor 10 reduces, for the equal strength of wind oar 104 of vertical axis rotor 10
Corresponding reduction.
Also referring to Fig. 2 and Fig. 3, in the present embodiment, vertical rack is tower 30.Tower 30 uses cast-in-place steel tube concrete
Native lattice.The compression strength of concrete is high, but bending resistance is very weak, and the bending resistance of steel, particularly shaped steel is strong, has
Good elastoplasticity, but be pressurized when easy unstability and lose axial compression resistance ability.And concrete filled steel tube can be by structure
The advantage of the two is combined together, and concrete can be made to be in side loaded state, and its compression strength can be significantly improved.Simultaneously because
The presence of concrete, improves the rigidity of steel pipe, and both play a role jointly, so as to greatly increase bearing capacity.Simultaneously
Front face area is reduced using the tower 30 of the rack-like body of lattice, the rigidity supported vertically is increased.
The column and linking beam of tower 30 are the steel-tube construction that flange is connected, and connecting bolt is used in high-strength bolt, steel pipe
Cast-in-place C50-C60Concrete, multiple steel platforms 301 are set in certain position, and steel platform 301 is made up of landing beam, and landing beam is used
Flanged (FLGD) steel-tube construction.The steel platform 301 is both the antitorque platform of the platform, sometimes tower 30 of installing generator 20.
The inside of tower 30 is used for operational inspection and maintenance provided with vertical elevator 302.Eliminate the labor climbed under big height
It is tired, while improving routing inspection efficiency.
The top of tower 30 is provided with the truss 303 of a horizontal positioned, and the two ends of truss 303 are stretched out in tower 30, this reality
Example is applied to wait place to stretch out, truss 303 is for fixed block car.The wire rope hoist on truss 303, is lifted using hoist engine and sent out
Motor 20 and vertical axis rotor 10, without other ground large crane.So the height of tower 30 is not just risen by ground
The constraint of the height of hoisting machinery.The rod member of truss 303 be connected by screw bolts (also for install lifting truss 303 when not
In addition using large-scale ground crane).Truss 303 and hoist engine located at the two ends of truss 303 together constitute tower 30 from
Lift-type crane, steel construction piece and the cast-in-place concrete of tower 30 are lifted when tower 30 is constructed.Exist in truss 303 and hoist engine
Generator 20 is no longer removed after installing, and is used in maintenance.
Also referring to Fig. 4 and Fig. 5, in the present embodiment, wind wheel rotating shaft 101 is cylindrical in shape and is rotatably arranged in the outer of tower 30
Wall, the inner side of wind wheel rotating shaft 101 is permanent-magnetic clamp.The stator 201 of generator 20 is additionally provided between the outer wall and permanent-magnetic clamp of tower 30,
There is air gap between stator 201 and permanent-magnetic clamp.
Above-mentioned, wind wheel rotating shaft 101 is cylindrical, and its inner side is permanent-magnetic clamp so that wind wheel rotating shaft 101 is used as hair when rotating
Rotor 202 in motor 20, by the continuous rotation cutting magnetic induction line of rotor 202 so as to generate electricity, the generator 20 of the structure is
External permanent magnet direct-drive generator 20.
Stator 201 includes the iron core of stator 201 and the winding of stator 201 being wound on the iron core of stator 201, and stator 201 is unshakable in one's determination
It is sheathed in tower 30.Wind wheel rotating shaft 101 is in steel platform 301.The axial end of wind wheel rotating shaft 101 and steel platform 301 it
Between be provided with bearing, by setting bearing to reduce the frictional force between wind wheel rotating shaft 101 and steel platform 301.Wind wheel rotating shaft 101 simultaneously
Diametrically constrained between tower 30 by level to constraint bearing.
Also referring to Fig. 6, vertical axis rotor 10 includes support arm 102, wind oar rotating shaft 103 and wind oar 104.Support arm
102 being connected in wind wheel rotating shaft 101 radially, at least three wind oars 104 are connected to the wind wheel by support arm 102 and turned
Axle 101, wind oar 104 is rotationally connected with support arm 102 by wind oar rotating shaft 103.
In the present embodiment, each wind oar 104 is connected in wind wheel rotating shaft 101 by two support arms 102, two support arms
Vertical support bar 105 is connected between 102, so that the rigidity between two support arms 102 is bigger.Two support arms 102
Wind oar 104 is divided into epimere wind oar 104, stage casing wind oar 104 and hypomere wind oar 104.
Wind oar 104 drives wind wheel rotating shaft 101 together to rotate, transformed wind energy into the wind-engaging masterpiece used time by support arm 102
Into the kinetic energy of vertical axis rotor 10, so that generator 20 generates electricity.Wind oar 104 is arranged on support arm 102 from wind wheel rotating shaft 101
Distalmost end, in vertical state, and wind oar rotating shaft 103 can opposed support structure 102 rotate, wind oar 104 is fixed in wind oar rotating shaft 103
On.
Wind oar rotating shaft 103 is connected on the longitudinal midline of wind oar 104, and wind oar 104 is fixedly connected with wind oar rotating shaft 103.Wind
Oar 104 is plate-like, and back is streamlined in other words on its surface, and fairshaped wind oar 104 has preferable exercise performance, reduces
The frictional force of wind oar 104 and wind.
For the rigidity that increase vertical axis rotor 10 is overall when rotating, the water suffered by each support arm 102 is preferably distributed
Put down to alternating force, horizontal support bar 106 is set between each adjacent support arm 102, and the horizontal support bar 106 is in the plane
Constitute polygon.
It should be noted that the support arm 102 of vertical axis rotor 10, horizontal support bar 106 and vertical support bar 105
To use lattice truss 303, to reduce the front face area of support arm 102, horizontal support bar 106 and vertical support bar 105, increase
Support stiffness.
In the present embodiment, the quantity of wind oar 104 is that 8, the i.e. quantity of support arm 102 are 16, and horizontal support bar 106 exists
Octagon is constituted on horizontal plane.The quantity of wind oar 104 is not limited to eight, can be 3,4, even 10.It can manage
Solution, the lifting surface area of real-time pitch-adjusting wind wheel is on the one hand relevant with Windward angle, on the one hand related to the quantity of wind oar 104, theoretical
The quantity of windward oar 104 is more, and lifting surface area is bigger.Due to do the wind sweeping area of big vertical axis rotor 10 as far as possible, manufacture is hung down
The truss 303 and wind oar 104 of d-axis wind wheel 10 should be from lightweight intensity height and the materials of advantage of lower cost.
As shown in Figure 7 and Figure 8, in another embodiment, the vertical axis rotor 10 includes wind wheel hub 108, support arm
102nd, wind oar rotating shaft 103 and wind oar 104.The wind wheel hub 108 includes axle sleeve 1081, spoke 1082 and hub circle 1083, the axle
Set 1081 is sheathed in the wind wheel rotating shaft 101, and described one end of spoke 1082 is connected with axle sleeve 1081, the other end and hub circle 1083
Connection.The outside of hub circle 1083 is evenly equipped with least three support arm 102 in the same direction with the radial direction of the hub circle 1083, institute
Wind oar 104 is stated to be rotationally connected with the support arm 102 by the wind oar rotating shaft 103.
By add wind wheel hub 108 so that vertical axis rotor 10 gyroscopic characteristics more preferably, reduce support arm 102 length,
Reduce the flexible deformation of support arm 102.The structure of wind wheel hub 108 is similar with the structure of cycle hub, in axle sleeve 1081 and hub
Pulling force spoke 1082 is provided between circle 1083, so that the shape of wind wheel hub 108 is more stablized.The structure of axle sleeve 1081 is lattice
Radiated on truss structure, the hub circle 1083 laterally that spoke 1082 intersects on axle sleeve 1081.The section of hub circle 1083 is in three
It is angular.The spoke 1082 that the outside of axle sleeve 1081 is provided with two annular hub circles 1083, two annular hub circles 1083 intersects
Forgotten about it by axle sleeve 1081 on hub circle 1083.The outside of hub circle 1083 is connected with support arm 102.Support arm 102 and wind oar 104 it
Between structure it is identical with the present embodiment.
Also referring to Fig. 9, vertical axis rotor 10 also includes wind direction sensing device and drive device 107.Wind direction sensing is filled
Put for sensing wind direction, the driving of drive device 107 be located at the wind oar 104 of half cycle windward all the time perpendicular to wind direction level point to,
The driving of drive device 107 positioned at contrary wind half cycle wind oar 104 all the time parallel to wind direction level point to.
In the present embodiment, a wind direction sensing device and a drive device 107 are equipped with each wind oar 104.Pass through
Wind direction sensing device judges the windward or leeward of wind oar 104 thereon, so that drive device 107 is fed back to, drive device 107
Control wind oar 104 is rotated.
Due to the presence of the angle of attack of wind oar 104, vertical axis rotor 10 could be rotated, and the angle of attack is relative to one end circular motion
Outer tangent line angle, i.e., when wind direction is parallel with wind oar 104, the angle of attack is zero, and wind oar 104 does not stress, and the angle of attack is not in the case of remaining
It is zero, wind oar 104 or by thrust or by resistance.
Because the driving force that vertical axis rotor 10 is rotated comes from the horizontal component of wind.Drive device 107 drives windward partly
The level point of the wind oar 104 in week all the time perpendicular to wind direction is to so that the driving force of half cycle is maximum windward.Drive device
The wind oar 104 of 107 driving contrary wind half cycles all the time parallel to wind direction level point to, though so that the resistance of contrary wind half cycle is not
Zero, but it is as small as possible, improve the utilization rate of wind energy.
Drive device 107 is motor, and the output shaft of motor is connected with wind oar rotating shaft 103.Vertical axis rotor 10 is operationally
Rotating always, wind oar 104 also in continuous change in real time, the change of its angle be it is continuous, be not the change of step evolution
Change, thus operationally noise is small, it is small to shake for vertical axis rotor 10, the work that can stablize.
It is appreciated that drive device 107 can also use hydraulic-driven, connecting rod in addition to can be using motor driving
Driving or the combination of the electronic connecting rod that surges driving.Motor is except that can be connected directly between the driving wind oar of wind oar rotating shaft 103 rotating shaft 103
Beyond rotation, by drive link wind oar rotating shaft 103 can also be driven to rotate, the structure is relatively conventional to will not be described here.
Realize that small area against the wind, improves the utilization rate of wind energy in different wind directions by the rotatable structure of wind oar 104.
And during vertical axis wind wheel is rotated, wind oar 104 is rotated in real time, turn to steady, continuous.
Embodiment 2
As shown in Figure 10, the present embodiment and the difference of embodiment 1 are, vertical rack is tower 30, and wind wheel rotating shaft 101 is in
Tubular and the outer wall for being rotatably arranged in tower 30, the relative stator 201 of rotor 202 of generator 20 are rotated.Rotor 202 turns with wind wheel
Axle 101 is connected by gearbox 40, and gear auxiliary driving is passed through with gearbox 40 in wind wheel rotating shaft 101 and rotor 202.
Above-mentioned, wind wheel rotating shaft 101 is rotated by gearbox 40 and gear auxiliary structure rotor driven 202, the position of stator 201
It is fixed, the constantly cutting magnetic induction line when rotating of rotor 202, so that generator 20 generates electricity.
Rotor 202 is permanent-magnetic clamp, in the present embodiment, and rotor 202 is inside stator 201, and the generator 20 of the structure is
Built-in type permanent-magnet directly drives generator 20.In another embodiment, rotor 202 is located at the outside of stator 201, the generator of the structure
20 be external permanent magnet direct-drive generator 20.
Stator 201 includes the iron core of stator 201 and the winding of stator 201 being wound on the iron core of stator 201, and stator 201 is unshakable in one's determination
On the inwall for being fixed on tower 30, the length of rotor 202 is more than the length of stator 201, stretching of the rotor 202 in stator 201
End is connected with gearbox 40, and gearbox 40 is connected with wind wheel rotating shaft 101.
Specifically, the inwall of wind wheel rotating shaft 101 is provided with gear and wind on circumference internal tooth form, the input shaft of gearbox 40
Take turns the internal tooth engagement of rotating shaft 101.The outer wall of rotor 202 is provided with the gear on the external tooth form of circumference, the output shaft of gearbox 40
Engaged with the external tooth form on rotor 202, so as to realize that wind wheel rotating shaft 101 drives the rotor 202 of generator 20 to rotate.
Wind wheel rotating shaft 101 is in steel platform 301.Axle is provided between the axial end and steel platform 301 of wind wheel rotating shaft 101
Hold, by setting bearing to reduce the frictional force between wind wheel rotating shaft 101 and steel platform 301.Wind wheel rotating shaft 101 simultaneously is diametrically
Constrained between tower 30 by level to constraint bearing.
Embodiment 3
Also referring to Figure 11 and Figure 12, difference of the present embodiment with implementing 1 is that vertical rack is in the vertical direction
A vertical axis rotor 10 is rotatably provided with the caged framework 50 of stacking, each caged framework 50 and generator described in one is installed with
20。
Caged framework 50 is made up of cruciform bracing 501 and upright of frame 502 radially, cruciform bracing 501 and framework
Column 502 is vertically connected.The light pipe concrete column that the upright of frame 502 is connected using flange.Build the material of caged framework 50
Structure is not limited to concrete filled steel tube, can also use steel construction, reinforced concrete structure, shield concrete filled steel tube circular rod
The combination of structure and multiple structures.
Independently rotated between vertical axis rotor 10 in each caged framework 50, each connection of vertical axis rotor 10 one generates electricity
Machine 20 generates electricity.
The string type vertical shaft wind power generating machine 1 of the present embodiment can build wind power station in various orographic conditions, especially
Be adapted to the roof construction wind power station in high-rise buildings or structures or Super High buildings or structures, but building post not necessarily
It is in the plane well-regulated polygon, therefore, being arranged at the post of caged framework 50 on roof can enter with the frame column of building
Row stress transition.See schematic diagram.
In all examples being illustrated and described herein, any occurrence should be construed as merely exemplary, without
It is that therefore, other examples of exemplary embodiment can have different values as limitation.
It should be noted that:Similar label and letter represents similar terms in following accompanying drawing, therefore, once a certain Xiang Yi
It is defined in individual accompanying drawing, then it further need not be defined and explained in subsequent accompanying drawing.
Embodiment described above only expresses the several embodiments of the application, and it describes more specific and detailed, but simultaneously
Therefore the limitation to the application scope can not be interpreted as.It should be pointed out that for the person of ordinary skill of the art,
On the premise of the application design is not departed from, various modifications and improvements can be made, these belong to the protection model of the application
Enclose.Therefore, the protection domain of the application should be determined by the appended claims.
Claims (10)
1. string type vertical shaft wind power generating machine, including vertical axis rotor and generator, the vertical axis rotor include with it is described
The connected wind wheel rotating shaft of generator, it is characterised in that
Also include vertical rack, vertical axis rotor string described at least two is located on the vertical rack and relatively described vertical branch
Frame is rotated, and each vertical axis rotor is connected with a generator for being fixedly arranged on the vertical rack.
2. string type vertical shaft wind power generating machine according to claim 1, it is characterised in that the vertical rack is tower;
The wind wheel rotating shaft is cylindrical in shape and is rotatably arranged in the outer wall of the tower, and the inner side of the wind wheel rotating shaft is permanent-magnetic clamp;
The stator of the generator, the stator and the permanent-magnetic clamp are additionally provided between the outer wall of the tower and the permanent-magnetic clamp
Between have air gap.
3. string type vertical shaft wind power generating machine according to claim 1, it is characterised in that the vertical rack is tower;
The wind wheel rotating shaft is cylindrical in shape and is rotatably arranged in the outer wall of the tower;
The rotor relative stator of the generator is rotated;
The rotor is connected with the wind wheel rotating shaft by gearbox, in the wind wheel rotating shaft and the rotor with the speed change
Case passes through gear auxiliary driving.
4. the string type vertical shaft wind power generating machine according to Claims 2 or 3, it is characterised in that the tower is using cast-in-place
Concrete filled steel tube lattice.
5. the string type vertical shaft wind power generating machine according to Claims 2 or 3, it is characterised in that set at the top of the tower
There is the truss of a horizontal positioned, the two ends of the truss are stretched out in the tower.
6. string type vertical shaft wind power generating machine according to claim 1, it is characterised in that the vertical rack is vertical
Vertical axis rotor described in one is rotatably provided with the caged framework stacked on direction, each caged framework and an institute is installed with
State generator.
7. string type vertical shaft wind power generating machine according to claim 1, it is characterised in that the vertical axis rotor includes branch
Brace, the rotating shaft of wind oar and wind oar;
Being connected in the wind wheel rotating shaft radially of support arm described at least three, the wind oar passes through the wind oar rotating shaft
It is rotationally connected with the support arm.
8. string type vertical shaft wind power generating machine according to claim 7, it is characterised in that the vertical axis rotor also includes
Wind direction sensing device and drive device;
The wind direction sensing device is used to sense wind direction;
Drive device driving be located at the wind oar of half cycle windward all the time perpendicular to wind direction level point to;
Drive device driving positioned at contrary wind half cycle the wind oar all the time parallel to wind direction level point to.
9. string type vertical shaft wind power generating machine according to claim 7, it is characterised in that between the adjacent support arm
Provided with support bar, the support bar constitutes regular polygon in the plane.
10. string type vertical shaft wind power generating machine according to claim 7, it is characterised in that the vertical axis rotor is also wrapped
Include wind wheel hub;
The wind wheel hub includes axle sleeve, spoke and hub circle, and the axle sleeve is sheathed in the wind wheel rotating shaft, described spoke one end with
Wind wheel rotating shaft is connected, and the other end is connected with hub circle;
At least three support arm in the same direction with the radial direction of the hub circle is evenly equipped with the outside of the hub circle, the wind oar passes through institute
It is connected on the support arm with stating wind oar axis of rotation.
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CN201710385250.5A CN107013411A (en) | 2017-05-26 | 2017-05-26 | String type vertical shaft wind power generating machine |
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CN201710385250.5A CN107013411A (en) | 2017-05-26 | 2017-05-26 | String type vertical shaft wind power generating machine |
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