CN203906183U - Two-way contra-rotating round rail carrying Y-shaped multi-blade fluid energy collecting multi-unit power generating windmill - Google Patents

Two-way contra-rotating round rail carrying Y-shaped multi-blade fluid energy collecting multi-unit power generating windmill Download PDF

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Publication number
CN203906183U
CN203906183U CN201420104079.8U CN201420104079U CN203906183U CN 203906183 U CN203906183 U CN 203906183U CN 201420104079 U CN201420104079 U CN 201420104079U CN 203906183 U CN203906183 U CN 203906183U
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windmill
circle
blade
rail
energy collecting
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刘海龙
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刘海龙
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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
    • Y02BCLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO BUILDINGS, e.g. HOUSING, HOUSE APPLIANCES OR RELATED END-USER APPLICATIONS
    • Y02B10/00Integration of renewable energy sources in buildings
    • Y02B10/30Wind power
    • 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
    • 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
    • Y02E10/72Wind turbines with rotation axis in wind direction

Abstract

The utility model relates to an ultra-high-power power generating windmill. A round rail carrying Y-shaped multi-blade device and a hydraulic energy collecting or pneumatic energy collecting multi-unit power generating system are creatively designed, and the wind power energy sources can be utilized on a large scale at high efficiency. The ultra-high-power power generating windmill has the following advantages that through the round rail carrying Y-shaped multi-blade design, the wind sweeping diameter of the windmill can reach more than 3,000m; through the two-way contra-rotating Y-shaped multi-blade design, the blade compaction degree ratio of the windmill reaches 100 percent; through the single-blade autoroatation wind combining multi-blade revolution design, the effects of regulating the blade surfaces to maintain the maximum wind receiving angle when the work air speed is reached, regulating the high-layer single blades to resist the wind by the minimum area layer by layer and only making single blades in the lower layer to work when the air speed is too high are achieved, the maximum tangential velocity of the blades of the windmill does no exceed the wind speed, and the maximum tip speed ratio is 1, so the windmill can work in strong wind; the hydraulic energy collecting or pneumatic energy collecting multi-unit power generating system is arranged on the ground, so the installation and the maintenance are convenient, the building cost is low, the installed capacity is high, and the installed capacity of the power generating unit can reach more than several millions of kilowatts.

Description

Two-wayly carry the multiple blade fluid energy collecting multicomputer wind motor for electric generation of Y-shaped to turning round rail bearing
[technical field]
The utility model belongs to and utilizes renewable and clean energy resource---the new technology of wind energy, relate to a kind of wind motor for electric generation of superhigh power, it is characterized in that innovative design circle rail bearing carries compound leaf sheet devices, windmill diameter is large, blade solidity is than high, hydraulic pressure energy collecting or air pressure energy collecting multicomputer power generation system, production electric energy is many, can utilize expeditiously on a large scale wind energy.
[background technique]
Wind motor for electric generation is in the past single tower windmill, unit generated energy is little, generating efficiency is low, the following technical barrier of main existence: the one, expand in proportion rotor diameter and can produce more electric power, also existing maximum wind power generator blade diameter brings that the deadweight of wind wheel and generator will significantly increase, bearing load strengthens and causes tired reduction working life, so can not exceed 200 meters; The 2nd, the solidity ratio of raising air vane, makes equal wind sweeping area obtain larger wind catching area, can produce more electric power; And the solidity of traditional air vane is than between 5%-20%, waste wind resource; The 3rd, improve rated wind speed, increase the most effective---generating dutation at full capacity, and traditional windmill cut-off wind speed is all generally 25m/s; And wind energy size is directly proportional to 3 powers of wind speed, in other words, we have only utilized the energy of lower wind speed, and considerable wind energy while having to abandon high wind; The utility model is two-way to be carried Y-shaped compound leaf sheet multicomputer energy collecting wind motor for electric generation and can overcome described technical barrier turning round rail bearing.
[model utility content]
The purpose of this utility model is to provide a kind of super giant wind power station that can make full use of wind resource, can build up at lower cost; The two-way of the utility model design carried the multiple blade fluid energy collecting multicomputer wind motor for electric generation of Y-shaped to turning round rail bearing, can solve traditional wind-powered electricity generation " three large technical barriers ": " compound leaf sheet is justified rail bearing and carried " makes windmill sweep wind diameter to reach more than 3000 meters; " two-way to turn, compound leaf sheet " design makes air vane solidity ratio reach 100%; " single blade rotation is revolved round the sun in conjunction with compound leaf sheet to wind " designed, and can improve the wind-engaging running effect of fan blade, and the maximum tangential velocity of blade of windmill is no more than wind speed, and tip-speed ratio is 1 to the maximum, so it can work in high wind; Hydraulic pressure energy collecting or air pressure energy collecting multicomputer power generation system, make that windmill electric motor power is large, the output quality of power supply is good, construction cost is low; This wind motor for electric generation can be left to design by height greatly, with 3000 meters of windmill diameters, 150 meters of calculating of height, 3000 × 150=450000 square metre of its cross section wind sweeping area, blade area 450000 × 13=5850000 square metre, generating set capacity can reach more than millions of kilowatts.
The utility model solves the technological scheme that its technical problem adopts:
Thisly two-wayly carry the multiple blade fluid energy collecting multicomputer wind motor for electric generation of Y-shaped to turning round rail bearing, comprise windmill Remote Automatic Control System (1), the Y-shaped compound leaf sheet (2) that single blade combines, the round rail windmill car body (3) of carrying compound leaf sheet, support the circular windmill track (4) of windmill car body operation, draw the round rail disjunctor drag-line car (5) moving of round rail windmill with suspension cable (209) Dou, hydraulic pressure energy collecting multicomputer power generation system (6) or air pressure energy collecting multicomputer power generation system (7) on circular drag-line Car Track; Wherein, Y-shaped compound leaf sheet (2) is by three circle circle rail windmill car body (3) carryings, by being equidistantly arranged in successively on round rail windmill car body (3); Circle rail windmill car body (3) has six circles, Y-shaped compound leaf sheet (2) opening angle of Y-shaped compound leaf sheet (2) opening angles of interior three circle circle rail windmill car bodies (3) carryings and the outer three round rail windmill car bodies of circle (3) carryings is contrary, makes circle rail windmill two-way to turning; Described circular drag-line Car Track has four circles, above circular drag-line Car Track, moving and justifying rail disjunctor drag-line car (5), every two circle circle rail disjunctor drag-line cars (5) are connected with middle Y-shaped compound leaf sheet (2) by suspension cable (209).
The utility model provides a kind of " circle rail bearing carries Y-shaped compound leaf sheet ", compound leaf face (20301), two the side compound leaf faces in left and right (20302) in the middle of described Y-shaped compound leaf sheet (2) comprises, between three faces, angle 120 is spent, equal in length, overlooks and is Y-shaped; The side that the top of side compound leaf face (20302) is provided with the miter angle that the leans forward compound leaf face (20303) that leans forward; Compound leaf face, by transferring perpendicular to ground the miter angle that turns forward to, makes by wind-force, the blade face of leaning forward to be formed to certain lift upwards in the time of multiple blade windward, thereby has reduced the stressed of mast (201) root; The compound leaf face of described Y-shaped compound leaf sheet (2) is combined by grid framework (204), single blade and mast, and grid framework (204) is made up of horizontal grid multiple, upper and lower multilayer, can report very flexibly extended blades; Y-shaped compound leaf sheet (2) is upper by being equidistantly arranged in round rail windmill car body (3), and windmill diameter is unrestricted, can reach more than 3000 meters.
The utility model provides two kinds of fluid energy collecting electricity-generating methods, and the medium that hydraulic pressure energy collecting multicomputer power generation system (6) is transmitted in the circulatory system for transformation of energy is water, is applicable to long-term non-icing area; The medium that air pressure energy collecting multicomputer power generation system (7) is transmitted in the circulatory system for transformation of energy is air, is applicable to extremely frigid zones.
Hydraulic pressure energy collecting multicomputer power generation system (6) is arranged between Nei Sanquan and outer three circle circle rail windmills, respectively organizes hydraulic pressure energy collecting multicomputer power generation system (6) and arranges by equidistant circumference along circle rail windmill track one side; Every group of hydraulic pressure energy collecting multicomputer power generation system (6) comprises reversible working oil hydraulic pump (601), oil hydraulic pump water inlet pipe (602), oil hydraulic pump outlet pipe (603), backwater supervisor (606), vibration means for main pipe for supplying water (605), aqueduct valve (607), high-pressure gas pressure tank (613), air compressor (612), circulating water pool (609), pump for adding liquid (608), hydraulic generator unit (616); Wherein, hydraulic generator unit (616) has multiple intelligent combination by series and parallel, motor aqueduct valve (619) is controlled to open by Remote Automatic Control System (1) and is made high-pressure water flow rush at fast hydraulic turbine generator, makes hydraulic generator unit (616) complete different capacity output procedure by various combination; Hydraulic generator unit (616) is connected between motor outlet pipe (618) and motor water inlet pipe (614), be arranged in parallel earth pressure release water recovery apparatus with generator set----reflow pipe and unidirectional Self controlling valve (615), in the time of generator set removal of load, high-pressure water flow can flow through from reflow pipe from a hydraulic turbine generator shunting part.
Described air pressure energy collecting multicomputer power generation system (7) is arranged between Nei Sanquan and outer three circle circle rail windmills, organizes air pressure energy collecting multicomputer power generation system (7) more and arranges by equidistant circumference along circle rail windmill track one side, every group of air pressure energy collecting multicomputer power generation system (7) comprises reversible working air pump (701), air pressure adjustment valve (702), air feed supervisor (703), return-air supervisor (704), air pump suction tude (705), air pump discharge pipe (706), tracheae valve (707), turbo-generator group (709), motor suction tude (710), motor row tracheae (711), low pressure gasholder (712), high pressure tank (713), motor tracheae valve (714), turbo-generator group (709) has multiple intelligent combination by series and parallel, can complete generator different capacity output procedure.
Relation and the working order of explained later blade transmission system:
Circle rail windmill car body (3) revolution is combined with single blade rotation, and so-called single blade rotation is the contiguous circumferential motion of single blade with respect to the blade axis of rotation (21202) central axis; So-called windmill revolution is that compound leaf sheet drives circle rail windmill car body (3) even to continue and move in a circle by circular track;
As shown in Figure 2, specifically describe fan blade in rotation and revolve round the sun in conjunction with in situation, air vane is blade angle, force-bearing situation and athletic performance in the time of several key position; In figure, Y-shaped compound leaf sheet (2) revolution that in setting, three circle circle rail bearings carry is carried out in clockwise manner, and Y-shaped compound leaf sheet (2) revolution that outer three circle circle rail bearings carry is carried out in counterclockwise mode, and thick arrow is wind direction;
First see the Y-shaped compound leaf sheet (2) that interior three circle circle rail bearings that clockwise mode moves carry, while operation the region periods of 7 o'clock to 11 o'clock, on the parallel grid framework (204) that covers compound leaf face in blade face of each single blade, make compound leaf facial plane become airfast wall, thereby be under pressure, promote under pressure Windmill rotary;
The plane of two side compound leaf faces (20302) and above a middle compound leaf face (20301) forms two " V " shape collection air ports that angle is 60 degree, and angle and above middle compound leaf face (20301) spacing equal 1/3 of middle compound leaf face (20301) length, leave this hollow position, be beneficial to collect air port and complete first acting air-flow by trying hard to recommend again another blade face work done, improve windmill efficiency
The wind-engaging angle difference of compound leaf facial plane, its region period that produces revolution benefit is also different, wind direction blows from south to north as shown in Figure 2, when interior three circle compound leaf sheets revolve round the sun clockwise, middle compound leaf face (20301) plane was at 7 o'clock to 11 o'clock, inner side compound leaf face (20302) plane was at 5 o'clock to 11 o'clock, outside compound leaf face (20302) plane can produce revolution benefit while running the region period of 7 o'clock to 1 o'clock, single blade of this period blade face is laid in the upper transfixion of grid framework (204) of compound leaf facial plane, and other regions that can not produce revolution benefit at compound leaf facial plane, by single blade, wind device for regulating direction is driven to single blade rotation, regulate blade windward angle, to reach best wind-engaging angle and best blowing area, and continuation produces revolution benefit,
And the orientation determination of wind the best wind-engaging angle of single blade blade face Ge region period, compound leaf sheet run to compound leaf sheet compound leaf facial plane can not produce revolution benefit the region period time, control single blade by windmill Remote Automatic Control System (1) and allow single blade rotation first single blade be adjusted to corresponding optimum wind-engaging angle to wind device for regulating direction, then allow single blade with revolve round the sun 1 to 2 the reverse rotation of rotating ratio; Single blade with the reverse rotation of revolution 1 to 2 rotating ratio, be conducive to single blade and remain best wind-engaging angle at area operation, and produce the benefit that revolves round the sun; Wind direction blows from south to north as shown in Figure 2, and when interior three circle compound leaf sheets revolve round the sun clockwise, in the time that compound leaf sheet is spent from 11 to its positive adverse wind face 3 points, revolution 120, single blade blade face reduces to 0 degree with revolution circumference corner cut from 60 degree, rotation 60 degree, rotating ratio is 1 to 2; When compound leaf sheet is from its positive adverse wind face 3 o'clock to 7 o'clock, revolution 120 while spending, single blade is increased to 60 degree with revolution circumference corner cut from 0 degree, rotation 60 degree, rotating ratio is 1 to 2; The corner cut of single blade and revolution circumference, single blade is produced be conducive to its component along the tangential motion of revolution circumference, single blade movement is at 11 o'clock during to 3 o'clock region periods, and component is more and more less, in 3 positions of positive adverse wind face, all single blades blade face is 0 degree with revolution circumference corner cut, and parallel with wind direction, component is 0, reach its minimum wind-exposuring area simultaneously, single blade movement is at 3 o'clock during to 7 o'clock region periods, and component is increasing, thereby makes single blade produce revolution benefit; In sum, utilize compound leaf sheet compound leaf facial plane revolution, the blade face rotation of single blade to wind, blade is in all fabulous wind-engaging running performances of regional;
Because high wind can apply very strong strength to windmill, this circle rail wind motor for electric generation can its blowing area of blade of free adjusting, can in high wind, work, concrete mode: compound leaf sheet is combined by some layers of single blade, the rotating ratio of each layer of single blade rotation can regulate wind device for regulating direction by single blade; As run into high wind, in the time that compound leaf sheet runs to positive adverse wind face position, single blade blade face is parallel with wind direction, by single blade to wind device for regulating direction, top compound leaf sheet single blade rotation and revolution rotating ratio are adjusted to 1 to 1, and sense of rotation is contrary, make high-rise single blade blade face all the time parallel with wind direction, all the time with minimum area wind resistance; Wind-force is stronger, be adjusted to the single blade number of plies in minimum area windproof upper strata more, in the time that only surplus lowermost layer list blade keeps out the wind work, its blade windward area can drop to 1/tens of its normal wind-exposuring area, and single blade is more at low layer, its structure is more firm, more can bear high wind, so it can work in superpower wind; As make windmill stop work done to resist superpower wind while making all single blades blade face parallel with wind direction.
The windmill Remote Automatic Control System (1) that the utility model adopts mainly contains the power unit composition of the core component of information and the collection awareness tool of information and message command, the core component of information is computer, the hypervisor of whole windmill is running here all, computer can utilize windmill hypervisor to send the order of fill order or access collection relevant information to the interface circuit of all information components, the information interface of computer is also connected with external network, shares and long-range object under the overall leadership thereby reach inside and outside information resources, the collection awareness tool of information is the information source of computer, various information gathering awareness tools can determine the wind direction, the relative bearing of each circle circle rail windmill car body (3) and circular windmill track (4) relative bearing when wind speed, temperature, generator speed and power, each layer of single blade rotation angle, windmill revolution, circle rail disjunctor drag-line car (5) and circle rail windmill, these information Perception parts moment are the data that computer provides use, and each information Perception parts has information-processing circuit and a set of perfect information interface circuit of certain ability, the power unit of message command mainly contains: Isolating Switch and the velocity ratio control to speed change control motor apparatus (21110) in wind device for regulating direction of between single blade, installing, mast (201) bottom actuating motor starts/cuts out, on vertical shaft (406), settling clutch device (407) to engage or disconnecting, reversible working oil hydraulic pump (601) and oil hydraulic pump water inlet pipe (602), the valve switch of oil hydraulic pump outlet pipe (603), reversible working air pump (701) and air pump suction tude (705), tracheae valve (707) switch of air pump discharge pipe (706), the adjusting of the total number of operation in parallel of reversible working oil hydraulic pump/air pump, water wheels/turbo-generator group has multiple intelligent combination by series and parallel, the adjusting of generator different capacity output procedure, circle rail disjunctor drag-line car (5) operation, oil hydraulic motor, servo motor transmission is to the driving force of side drive gear (508), the adjusting of velocity ratio, the adjusting that circle rail disjunctor drag-line car (5) controllable moving joint connects, a large amount of electronic switch and magnetic switch and actuating motor facilities of using are carried out in exercises, these are extensions of the hand of computer, above information core, information Perception, information and executing parts three major types information facility has formed the automation hard environment of windmill jointly, windmill hypervisor software environment operates in computer, be divided into five subroutines: the self-check program of windmill, the startup of windmill the collect folk songs program, windmill of many circumstances of reset routine, windmill of collecting folk songs stops the program of collecting folk songs, windmill error protection program out of service, as long as meet the condition that enters a certain subroutine, computer just can enter the running state of this program, the management of whole windmill is exactly in the middle of these five subroutines, according to condition in many ways, setup parameter separately, the process of switching flexibly and moving.
The beneficial effects of the utility model are:
1, justify the steady seat of Y-shaped compound leaf sheet operation that rail bearing carries as mountain, multiple blade design can be greatly can height;
2, two-way on circular track to turning, the highest tip-speed ratio is 1 to Internal and external cycle windmill car body, and overlength radius still keeps less angular velocity after making its rotation reach at a high speed, can in high wind, move;
3, hydraulic pressure energy collecting or air pressure energy collecting multicomputer power generation system (7), makes that windmill electric motor power is large, the output quality of power supply is good, construction cost is low;
4, the single blade of 360 degree rotation is to the design of wind device for regulating direction, can tackle safely high wind, and fan blade face is cloth, conduct oneself with dignity little, and low cost of manufacture, bird strike is without injury, ecological, environmental protective;
5, the solidity of air vane is than high, and collection wind area is large, and gentle breeze can start, and work wind speed range is large, and cost poor efficiency is high, the suitable especially super giant wind power station that is built into.
[brief description of the drawings]
Fig. 1: the panorama of overlooking that is windmill of the present utility model;
Fig. 2: be air vane in the time of several key position, the schematic top plan view of blade angle and stressed running;
Fig. 3-1: the structural representation that is single Y-shaped compound leaf sheet;
Fig. 3-2: the middle blade face structural drawing that is Y-shaped compound leaf sheet;
Fig. 3-3: the lateral lobe face structural drawing that is Y-shaped compound leaf sheet;
Fig. 3-4: the grid frame structure figure that is Y-shaped compound leaf sheet;
Fig. 3-5: the netting structural drawing that is Y-shaped compound leaf sheet;
Fig. 3-6: the suspension cable structure figure that is Y-shaped compound leaf sheet;
Fig. 4-1: the three-dimensional structure diagram that is single blade of rotating around mast after horizontal line B line in Fig. 3-3, C line and vertical line F line, H line intersecting area amplify;
Fig. 4-2: the side-looking structural drawing that is single blade of rotating around mast;
Fig. 4-3: the structural drawing of facing that is single blade of rotating around mast;
Fig. 4-4: be the three-dimensional structure diagram that is fixed on the single blade on the axis of rotation after horizontal line B line in Fig. 3-3, C line and vertical line D line, E line intersecting area amplify;
Fig. 4-5: be the side-looking structural drawing that is fixed on the single blade on the axis of rotation;
Fig. 4-6: be the front view structural drawing that is fixed on the single blade on the axis of rotation;
Fig. 4-7: the three-dimensional structure diagram that is triangle list blade;
Fig. 4-8: the plan view that is triangle list blade;
Fig. 4-9: the three-dimensional structure diagram that is polygonal disjunctor blade after amplify in horizontal line A line in Fig. 3-3, B line and vertical line G line, I line region;
Fig. 5-1: be the plan structure figure that has the windmill part of three circle circle rails, Y-shaped compound leaf sheet is wherein to remove the plan structure figure that side leans forward after compound leaf face;
Fig. 5-2: be the plan structure figure in controllable extensible active connection place that has the windmill part of three circle circle rails, Y-shaped compound leaf sheet is wherein to remove the plan structure figure that side leans forward after compound leaf face;
Fig. 6: be hydraulic pressure energy collecting multicomputer power generation system schematic diagram;
Fig. 7: be air pressure energy collecting multicomputer power generation system schematic diagram;
Fig. 8-1: the three-dimensional structure diagram that is circle rail windmill car body;
Fig. 8-2: the three-dimensional structure diagram that is circular windmill track;
Fig. 8-3: be the three-dimensional structure diagram after circular windmill track combines with circle rail windmill car body;
Fig. 9: the three-dimensional structure diagram that is circle rail disjunctor drag-line car;
In figure:
1, windmill Remote Automatic Control System; 2, Y-shaped compound leaf sheet; 201, mast; 201-1, mast; 201-2, mast; 201-3, mast; 201-4, mast; 201-5, mast; 201-6, mast; 201-7,45 degree Dou masts lean forward; 202, side mast; 202-1, side mast; 202-2, side mast; 202-3, side mast; 202-4, side mast; 202-5, side mast; 202-6, side mast; 202-7, side mast; 202-8, side mast; 202-9, side mast; 20301, middle compound leaf face; 20302, side compound leaf face; 20303, the side compound leaf face that leans forward; 204, grid framework; 205, grid framework supporting frame; 20501, Dou cradling piece; 20502, supporting post; 20503, horizontal connecting rod; 20504, longitudinal connecting rod; 206, netting; 207, horizontal support post; 208, vertical pulling rope; 209, suspension cable; 210, cross bar; 211, around the rhombus list blade of mast left rotation and right rotation; 21101, blade surface; 21102, single blade bearing on mast; 21103, single blade rack bar; 21104, single blade frame; 21105, blade is strengthened rope; 21106, single blade supporting post; 21107, tow rope; 21108, single blade is around mast swing pinion; 21109, endless drive chain; 21110, speed change control motor apparatus; 212, be fixed on the axis of rotation and can spend the rhombus list blade rotating in left and right 360; 21201, blade surface; 21202, the blade axis of rotation; 21203, single blade rack bar; 21204, single blade frame; 21205, blade is strengthened rope; 21206, single blade supporting post; 21207, single blade tow rope; 21208, single blade axis of rotation gear; 213, triangle list blade; 21301, blade surface; 21302, single blade rotor; 21303, blade rack bar; 21304, single blade frame; 21305, power traction rope; 21306, scrolling wheel; 21307, the pulley on triangle-frame; 21401, the pentagon list blade rotating around mast; 21402, be fixed on the axis of rotation and can spend the pentagon list blade rotating in left and right 360; 215, horizontal support framework; 216, polygonal disjunctor blade; 21601, blade surface; 21602, rotating shaft; 21603, power traction rope; 21604, single blade frame; 21605, scrolling wheel; 21606, pulley; 21607, drive wheel; 21608, tow rope in cross bar; 217, single blade shaft joint; 3, justify rail windmill car body; 301, car body siding track; 302, lower wheel; 303, upper wheel; 304, middle left wheel; 305, middle right wheel; 306, oil hydraulic pump; 307, pneumatic pump; 308, actuating motor; 309, oil pipe; 310, tracheae; 311, gas storage pressure tank; 312, gas holder; 4, circular windmill track; 401, lower railway; 402, upper race; 403, middle race; 404, the gear of vertical shaft; 405, circle wheel; 406, vertical shaft; 407, clutch device; 5, justify rail disjunctor drag-line car; 501, lower railway; 502, upper race; 503, middle race; 504, drag-line car siding track; 505, upper supporting wheel; 506, lower support wheel; 507, horizontal support wheel; 508, side drive gear; 509, side auxiliary drive circle wheel; 510, vertical shaft; 511, actuating motor; 512, variable speed controllable oil hydraulic motor; 6, hydraulic pressure energy collecting multicomputer power generation system; 601, reversible working oil hydraulic pump; 602, oil hydraulic pump water inlet pipe; 603, oil hydraulic pump outlet pipe; 604-1, water main valve; 604-2, water main valve; 604-3, water main valve; 604-4, water main valve; 604-5, water main valve; 604-6, water main valve; 604-7, water main valve; 604-8, water main valve; 605, vibration means for main pipe for supplying water; 606, backwater supervisor; 607, aqueduct valve; 608, pump for adding liquid; 609, circulating water pool; 610, tracheal pressure; 611, air valve; 612, air compressor; 613, high-pressure gas pressure tank; 614, motor water inlet pipe; 615, unidirectional Self controlling valve; 616, hydraulic generator unit; 617, cable; 618, motor outlet pipe; 619, motor aqueduct valve; 7, air pressure energy collecting multicomputer power generation system; 701, reversible working air pump; 702, air pressure adjustment valve; 703, air feed supervisor; 704, return-air supervisor; 705, air pump suction tude; 706, air pump discharge pipe; 707, tracheae valve; 708-1, main tracheae valve; 708-2, main tracheae valve; 708-3, main tracheae valve; 708-4, main tracheae valve; 708-5, main tracheae valve; 708-6, main tracheae valve; 708-7, main tracheae valve; 708-8, main tracheae valve; 709, turbo-generator group; 710, motor suction tude; 711, motor row tracheae; 712, low pressure gasholder; 713, high pressure tank; 714, motor tracheae valve.
[embodiment]
Below in conjunction with the drawings and specific embodiments, the utility model is described in further detail, and the utility model is not limited to these mode of executions.
As shown in Figure 1, two-wayly carry the multiple blade fluid energy collecting multicomputer wind motor for electric generation of Y-shaped to turning round rail bearing, comprise windmill Remote Automatic Control System (1), the Y-shaped compound leaf sheet (2) that single blade combines, the round rail windmill car body (3) of carrying Y font compound leaf sheet (2), the circular windmill track (4) of carrying circle rail windmill car body (3) operation, draw the round rail disjunctor drag-line car (5) moving of round rail windmill on circular drag-line Car Track with suspension cable (209) Dou, hydraulic pressure energy collecting multicomputer power generation system (6) or air pressure energy collecting multicomputer power generation system (7), wherein said Y-shaped compound leaf sheet (2) is by three circle circle rail windmill car body (3) carryings, by being equidistantly arranged in successively on round rail windmill car body (3), described round rail windmill car body (3) has six circles, Y-shaped compound leaf sheet (2) opening angle of Y-shaped compound leaf sheet (2) opening angles of interior three circle circle rail windmill car bodies (3) carryings and the outer three round rail windmill car bodies of circle (3) carryings is contrary, makes circle rail windmill two-way to turning, described circular drag-line Car Track has four circles, above circular drag-line Car Track, moving and justifying rail disjunctor drag-line car (5), every two circle circle rail disjunctor drag-line cars (5) are connected with middle Y-shaped compound leaf sheet (2) by suspension cable (209).
As shown in Fig. 3-1, compound leaf face (20301), two the side compound leaf faces in left and right (20302) in the middle of Y-shaped compound leaf sheet (2) comprises, between three faces, angle 120 is spent, equal in length, overlooks and is Y-shaped; The side that the top of side compound leaf face (20302) is provided with the miter angle that the leans forward compound leaf face (20303) that leans forward; Compound leaf face, by transferring perpendicular to ground the miter angle that turns forward to, makes by wind-force, the blade face of leaning forward to be formed to certain lift upwards in the time of multiple blade windward, thereby has reduced the stressed of mast (201) and side mast (202) root; Left side compound leaf face (20302) has mast (201-5) to support on left circles rail windmill car body (3), and the front and back of mast (201-5) have two side masts (202-1,202-2) be connected and supported by grid framework (204); Right side compound leaf face (20302) has mast (201-6) to support on right circles rail windmill car body (3), and the front and back of mast (201-6) have two side masts (202-3,202-4) be connected and supported by grid framework (204).
Fig. 3-1,3-2,3-3 in conjunction with referring to, three faces of Y-shaped compound leaf sheet (2) are combined by grid framework (204), single blade and mast, grid framework (204) is made up of horizontal grid multiple, upper and lower multilayer; In the network of grid framework (204), be fixed on the axis of rotation and can spend the rhombus list blade (212) rotating in left and right 360; Rhombus list blade (211) around mast left rotation and right rotation is installed in the network framework on mast (201-2,201-3,201-4,201-5,201-6); Between the left side of mast (201-1), right side network of triangle case frame, one diabolo list blade (213) is installed, is become diabolo list blade (213) and mast to be rotatably connected and can rotate by left and right 120 degree between left side, right side network of triangle case frame; The tie point lateral separation of left side, right side network of triangle case frame and mast (201-1) is greater than 0.27 times of rhombus list blade 212 turning radius, so that mast (201-1) left side, right side first row rhombus list blade 212 do not contact mutually in the time that 360 degree rotate; Y-shaped compound leaf sheet center mast (201-1) top separates by vertical pillars the 45 degree Dou masts (201-7) that lean forward, the 45 degree Dou masts (201-7) that lean forward are connected with the grid framework that leans forward (204) on left side, right side, become diabolo list blade (213) taking lean forward 45 degree Dou mast (201-7) posts as axle can left and right 120 degree rotations between left side, right side network of triangle case frame; The upper and lower multilayer of the grid framework (204) that leans forward, is fixed in the network in mesosphere on the axis of rotation and can spends the rhombus list blade (212) rotating in left and right 360, and the axis of rotation is parallel with the 45 degree Dou masts (201-7) that lean forward; In the pentagon grid of the superiors, be fixed on the axis of rotation and can spend the pentagon list blade (21402) rotating in left and right 360; Grid framework (204) orlop that leans forward is connected with cross bar (210), form horizontal multiple irregular polygon grid, polygonal disjunctor blade (216) is arranged on below polygonal mesh, taking cross bar (210) as axle, at horizontal plane with lean forward between grid framework can upper and lower 45 degree rotations; Cross bar (210) is connected with the grid framework (204) perpendicular to ground downwards, forms horizontal multiple pentagon grid, is fixed on the axis of rotation and can spends the pentagon list blade (21402) rotating in left and right 360 in grid.
Fig. 4-1,4-2,4-3 in conjunction with referring to, the pentagon list blade (21401) rotating around mast, be installed in the pentagon grid of compound leaf slice graticule framework (204), centered by mast (201), axle is also rotatably connected by three single blade bearings (21102) and mast (201), does equidirectional being in transmission connection by single blade around mast swing pinion (21108) and single blade axis of rotation gear (21208) (in conjunction with referring to Fig. 3-2) with endless drive chain (21109); The single blade (211) rotating around mast, centered by mast (201), axle is also rotatably connected by three single blade bearings (21102) and mast (201), mast (201) on compound leaf sheet blade face is fixedly connected with grid framework (204), mast (201) both sides form the symmetrical right-angled triangle framework of arranging up and down, a pair of triangular framing, form a rhombus grid, in a rhombus grid, a single blade (211) rotating around mast is installed; The single blade (211) rotating around mast is provided with single blade frame (21104), single blade rack bar (21103), blade surface (21101) adopts the extraordinary cloth that has blade to strengthen rope (21105), single blade supporting post (21106) is fixedly connected with perpendicular to blade center and with single blade bearing (21102) of centre, and is rotatably connected by single blade bearing (21102) and mast (201); Single blade supporting post (21106) is fixedly connected by many tow ropes (21107) and single blade frame (21104), single blade rack bar (21103), tow rope (21107) claims to distribute at blade left and right side, vis-a-vis, can increase the number (40 for excellent) of tow rope (21107) according to the structural strength of single blade; Single blade is fixedly connected with single blade rack bar (21103) frame around mast swing pinion (21108), tip edge is the alignment of waist midpoint under rhombus blade, around mast swing pinion taking mast (201) as axle, be rotatably connected by single blade bearing (21102) on mast and mast (201), single blade is identical with diameter and the number of teeth of single blade axis of rotation gear (21208) around mast swing pinion (21108), and does equidirectional power transmission connection with endless drive chain (21109) (combination is referring to Fig. 3-2); In mast (201), there is single blade bearing (21102), speed change control motor apparatus (21110) (in conjunction with referring to Fig. 8-1) by gear transmission to the single blade bearing (21102) on mast (201), single blade bearing (21102) drives single blade to rotate around mast swing pinion (21108), then drives one group of composition linkage list blade to do in the same way synchronously rotation by endless drive chain (21109); Speed change control motor apparatus (21110) is provided with sensor, can carry out auto-control by Remote Automatic Control System (1).The pentagon list blade (21401) that rotates around mast, be not installed with single blade around the single blade (211) rotating around mast of mast swing pinion (21108) by single blade bearing (21102) driven rotary on mast (201), single blade bearing (21102) on mast (201) drives its rotation by speed change control motor apparatus (21110) by gear transmission, speed change control motor apparatus (21110) is provided with sensor, can carry out auto-control by Remote Automatic Control System (1).
Fig. 4-4,4-5,4-6 in conjunction with referring to, be fixed on the axis of rotation and can spend the pentagon list blade (21402) rotating in left and right 360, be installed in the pentagon grid of compound leaf slice graticule framework (204), by the rhombus list blade 212 of the fixing series winding of single blade shaft joint (217) lower floor, be fixed on the axis of rotation and can spend the rhombus list blade (212) rotating in left and right 360, be installed in the network of compound leaf slice graticule framework (204), the upper and lower two of the axis of rotation and the grid framework (204) of single blade are rotatably connected, can freely rotate by 360 degree, the axis of rotation of single blade is fixedly connected with single blade frame (21204), in single blade frame (21204), be provided with single blade rack bar (21203), the extraordinary cloth that blade surface (21201) can adopt high strength light shaped material to make, and supporting employing blade is strengthened rope (21205) and is reinforced, single blade supporting post (21206) is vertically fixedly connected with the blade axis of rotation (21202) through blade center, single blade supporting post (21206) is fixedly connected by many single blade tow ropes (21207) and single blade frame (21204), single blade rack bar (21203), the blade axis of rotation (21202), and single blade tow rope (21207) is symmetrical in leave dual sides, can increase the number of single blade tow rope (21207) according to the structural strength of single blade, taking 32 as excellent, single blade axis of rotation gear (21208) is centered by the blade axis of rotation (21202), tip edge is waist or lower waist midpoint on rhombus blade, same layer list blade axis of rotation gear (21208) and single blade with endless drive chain (21109), are made equidirectional power transmission and are connected between mast swing pinion (21108), single blade of axis of rotation gear is installed on the network of grid framework (204), the single blade without axis of rotation gear by the fixing series winding of single blade shaft joint (217) up and down, they by single blade shaft joint (217) on the blade section that places an order combine, do coaxial rotating in same direction, every 2-5 layer list blade section combination, lower leaf combination in formation, coaxial compound single blade in the same way.
Fig. 4-7,4-8 in conjunction with referring to, described triangle list blade (213), paired mounting leans forward between grid framework (204) at Y-shaped compound leaf sheet, triangle list blade (213) is provided with single blade frame (21304), blade rack bar (21303), blade surface (21301) adopts extraordinary cloth, and triangle list blade (213) is rotatably connected by single blade rotor (21302) and mast (201); An angle of triangle list blade (213) is connected with power traction rope (21305), power traction rope (21305) is connected with scrolling wheel (21306) by the pulley (21307) on left side, right side triangle-frame, and speed change control motor apparatus (21110) pulls power traction rope (21305), power traction rope (21305) to pull triangle list blade (213) between left side, right side triangle-frame, to do 120 degree rotations by controlling scrolling wheel (21306) rotation; Speed change control motor apparatus (21110) is provided with sensor, can carry out auto-control by Remote Automatic Control System (1), paired triangle list blade (213) is pulled open with the wind time cover on triangle-frame to keep out the wind, in the time of contrary wind, rotate to the minimum angle wind sheltering of keeping out the wind.
As shown in Fig. 4-9, polygonal disjunctor blade (216), being arranged on Y-shaped compound leaf sheet leans forward between grid framework (204) and horizontal support framework (215), polygonal disjunctor blade (216) is provided with single blade frame (21604), blade surface (21601) adopts extraordinary cloth, and polygonal disjunctor blade (216) is rotatably connected by rotating shaft (21602) and cross bar (210); Each angle of polygonal disjunctor blade (216) is connected with power traction rope (21603) respectively, and power traction rope (21603) does annular ring by horizontal support framework (215) with the drive wheel (21607) in the pulley (21606), the cross bar (210) that lean forward on grid framework framework and is connected; Speed change control motor apparatus (21110) does rotation forward or backwards by controlling scrolling wheel (21605), pull tow rope (21608) in cross bar, pull drive wheel (21607) and power traction rope (21603), thus pull polygonal disjunctor blade (216) at horizontal support framework (215), lean forward and between grid framework, do upper and lower 45 degree rotations; Speed change control motor apparatus (21110) is provided with sensor, can carry out auto-control by Remote Automatic Control System (1), polygonal disjunctor blade (216) is upwards covered on the grid framework that leans forward with the wind time keep out the wind, in the time of contrary wind, transfer to horizontal support framework (215) with the minimum angle wind sheltering of keeping out the wind.
As Fig. 3-2, shown in 3-3, endless drive chain (21109) in wind device for regulating direction is connected to multiple single blades and form one group of composition linkage list blade, speed change control motor apparatus (21110) in mast (201) drives each group of endless drive chain (21109) independent rotation, oil hydraulic pump (306) (adopting pneumatic pump (307) at extremely frigid zones) on circle rail windmill car body (3), actuating motor (308) transmits power to the speed change control motor apparatus (21110) in mast (201) by the oil pipe (309) in mast (201) (adopting tracheae (310) at extremely frigid zones), the every group of composition linkage list blade coming on (2) three faces of auto-control Y-shaped compound leaf sheet by Remote Automatic Control System (1) can do in the same way synchronously rotation separately.
As shown in Figure 3-4, the network framework (204) of Y-shaped compound leaf sheet (2) is connected taking cradling piece as frame and with mast (201), and mast (201) is fixed on round rail windmill car body (3); Grid framework supporting frame (205) is fixedly connected on grid framework (204) node, in the symmetrical installation of grid framework (204) front-back, formed by Dou cradling piece (20501), supporting post (20502), horizontal connecting rod (20503), longitudinal connecting rod (20504); The every 3 layers of network of compound leaf Mian Zhong lower floor are installed the grid framework supporting frame (205) that one deck laterally connects, compound leaf face at the middle and upper levels each layer of network is installed laterally the longitudinally grid framework supporting frame (205) of integrated connection, can play reinforcement effect to grid framework (204).
As shown in Fig. 5-1, Y-shaped compound leaf sheet (2) is installed three compound leaf faces equal in length of single blade, and compound leaf face length degree equals 3/4 of Y-shaped compound leaf sheet (2) fore-and-aft clearance; Between the upper Y-shaped compound leaf sheet (2) of circle rail windmill car body (3), the middle compound leaf face (20301) on middle circle rail uninterruptedly connects as one by grid framework (204); The side compound leaf face (20302) of both sides, is connected with mast (201-1) substantially horizontal by vertical pulling rope (208); Left side compound leaf face (20302) has mast (201-5) to support on left circles rail windmill car body (3), and the front and back of mast (201-5) have two side masts (202-1,202-2) be connected and supported by grid framework (204); Right side compound leaf face (20302) has mast (201-6) to support on right circles rail windmill car body (3), and the front and back of mast (201-6) have two side masts (202-3,202-4) be connected and supported by grid framework (204); , co-orbital side mast (202-3) and side mast (202-4) are uninterruptedly connected as one by netting (206) co-orbital side mast (202-1) and side mast (202-2) by netting (206) (referring to Fig. 3-5); Middle compound leaf face 20303 has 4 masts (201-1,201-2,201-3,201-4) to support, uninterruptedly connect as one by grid framework (204) at middle circle rail windmill car body (3); Mast (201-5,201-4,201-6) transverse row is in line and passes through netting (206) and is laterally connected, side mast (202-2,202-4) is in line and passes through netting (206) with mast (201-3) transverse row and is laterally connected, and side mast (202-1,202-3) is in line and passes through netting (206) with mast (201-1) transverse row and is laterally connected; Mast (201-5), side mast (202-1,202-2), be laterally connected with homonymy circle rail disjunctor drag-line car (5) by suspension cable (209) (referring to Fig. 3-6) separately; Mast (201-6), side mast (202-3,202-4), be laterally connected with homonymy circle rail disjunctor drag-line car (5) by suspension cable (209) separately; The horizontal support post (207) that is 90 degree angles with compound leaf face is directly fixedly connected on mast (201-2) and mast (201-3), and horizontal support post (207) is connected with grid framework (204) node by netting (206); Two outsides at mast (201-2) are laterally connected with circle rail disjunctor drag-line car (5) by suspension cable (209); Be fixedly connected on mast (201-1) perpendicular to the horizontal support post (207) of mast (201-1) upper, be connected with side compound leaf face (20302) by vertical pulling rope (208).
Fig. 8-1,8-2,8-3 in conjunction with referring to, there are lower railway (401) and upper race (402) in circular windmill track (4) bi-side of carrying circle rail windmill car body operation, middle part has middle race (403), inside that gear (404) and the circle wheel (405) of vertical shaft are installed above; Described round rail windmill car body (3) both sides are installed with lower wheel (302) and upper wheel (303) are installed on car body siding track (301), siding track, in the middle of being installed with above car body, left wheel (304), middle right wheel (305), is carrying oil hydraulic pump (306) or pneumatic pump (307), actuating motor (308), Y-shaped compound leaf sheet (2); The outside of windmill car body siding track (301) is provided with tooth bar fixed groove and is meshed with the gear (404) of vertical shaft; The inner side of windmill car body siding track (301) is that plate rail engages with circle wheel (405), make windmill car body siding track (301) engage very close to each other with gear (404) and the circle wheel (405) of vertical shaft, on upper wheel (303), head on race (402), lower wheel (302) is pressing down lower railway (401), middle left wheel (304), middle right wheel (305) be to race (403) in sandwich, makes circle rail windmill car body (3) all the time along circular windmill track (4) operation and do not derail.
Fig. 8-1, 3-2, 3-3 in conjunction with referring to, described round rail windmill car body (3) is carrying compound leaf sheet, the mast (201) of compound leaf sheet is hollow cylinder, inside is provided with oil pipe (309), speed change control motor apparatus (21110), a gas storage pressure tank (311) is installed under each mast (201), one group of series-parallel oil hydraulic pump (306), multiple oil hydraulic pumps (306) by with each on wheel (303) be connected, the rotation of upper wheel (303) makes oil hydraulic pump (306) pressurization form high-voltage drive liquid and comes and goes operation along oil pipe (309) circulation, Energy transfer is arrived to the speed change control motor apparatus (21110) in mast (201), for the single blade (211) rotating around mast provides power, single blade is laterally made equidirectional transmission link by endless drive chain (21109), thereby for every one deck list blade provides power by certain angular velocity rotation, the oil hydraulic pump (306) of an actuating motor (308) and its driving is installed in mast (201) bottom, when windmill reaches startup wind speed, and single blade is need to be to wind tuning time, start actuating motor (308) by Remote Automatic Control System (1), drive oil hydraulic pump (306) to make transmission fluid circulation transmission, switch to and provide power tuning by upper wheel (303) rotating drive oil hydraulic pump (306) so that all single blades, to wind tuning, are closed actuating motor (308) after windmill rotation, at extremely frigid zones, the oil hydraulic pump (306) on circle rail windmill car body (3) is used pneumatic pump (307) instead, a gas holder (312) is installed under each mast (201), one group of series-parallel pneumatic pump (307), multiple pneumatic pumps (307) by with each on wheel (303) be connected, the rotation of upper wheel (303) makes pneumatic pump (307) pressurization form pressurized gas and is transported to gas holder (312), gas holder (312) connects the interior tracheae of mast (201) (310) Energy transfer is arrived on the speed change control motor apparatus (21110) in mast (201), for the single blade (211) rotating around mast provides power, start wind speed and gas holder (312) air pressure when not enough when windmill reaches, starting driven by servomotor pneumatic pump (307) be that gas holder (312) aerating is pressurizeed.
As shown in Fig. 8-2,8-3, on the ground at circular windmill track (4) place by reversible working oil hydraulic pump (601) (or reversible working air pump (701)) is equidistantly installed successively; The gear (404) of the each group of vertical shaft of installing in circular windmill track (4) and circle wheel (405) clip windmill car body siding track (301), the gear (404) of each vertical shaft respectively connects a ground reversible working oil hydraulic pump (601) (or reversible working air pump (701)) by vertical shaft (406), can be the power transmission of circle rail windmill car body (3) running to reversible working oil hydraulic pump (601) (or reversible working air pump (701)); On vertical shaft (406), settling clutch device (407), and can carry out auto-control clutch joint or disconnect by Remote Automatic Control System (1); Circular windmill track (4) shown in Fig. 8-2,8-3 has adopted viaduct beam type to install, and certainly also can adopt ground roadbed formula to install.
Hydraulic pressure energy collecting multicomputer power generation system (6) is arranged between Nei Sanquan and outer three circle circle rail windmills, respectively organizes hydraulic pressure energy collecting multicomputer power generation system (6) and arranges by equidistant circumference along circle rail windmill track one side; As shown in Figure 6, every group of hydraulic pressure energy collecting multicomputer power generation system (6) comprises reversible working oil hydraulic pump (601), oil hydraulic pump water inlet pipe (602), oil hydraulic pump outlet pipe (603), backwater supervisor (606), vibration means for main pipe for supplying water (605), aqueduct valve (607), high-pressure gas pressure tank (613), air compressor (612), circulating water pool (609), pump for adding liquid (608), hydraulic generator unit (616); Its medium transmitting in the circulatory system for transformation of energy is water, is applicable to long-term non-icing area; High-pressure hydraulic in high-pressure gas pressure tank (613) converts to after electric energy by motor water inlet pipe (614) access hydraulic generator unit (616) generating, and water flows to circulating water pool (609) along motor outlet pipe (618); Circulating water pool (609) T is connected to filler pipe, water valve, pump for adding liquid (608), can add water; The interior gas of high-pressure gas pressure tank (613) can keep larger volumetric spaces, reduce system liquid pressure water hammer under certain pressure, the upper T of high-pressure gas pressure tank (613) is connected with tracheal pressure (610), air valve (611), air compressor (612), can regulate the volumetric spaces ratio of the interior gas of high-pressure gas pressure tank (613) and water; The bottom of circular windmill track is installed with reversible working oil hydraulic pump (601), and reversible working oil hydraulic pump (601) is the oil hydraulic pump that mechanical energy can be converted to the pressure energy of liquid, also the pressure energy of liquid can be converted to the reversible working of mechanical energy; Each reversible working oil hydraulic pump (601) respectively with oil hydraulic pump water inlet pipe (602), airtight connection of oil hydraulic pump outlet pipe (603) that aqueduct valve (607) is installed, many oil hydraulic pump water inlet pipes (602) are parallel to vibration means for main pipe for supplying water (605), and many oil hydraulic pump outlet pipes (603) are parallel to backwater supervisor (606); Vibration means for main pipe for supplying water (605), backwater supervisor (606) extend along circular windmill track, several reversible working liquid pressure pumps in parallel;
Next the working principle of hydraulic pressure energy collecting multicomputer power generation system (6) regulation and control windmill car body synchronous operation is described: the interior three circle circle rails of every group of hydraulic pressure energy collecting multicomputer power generation system (6) windmill for a set of vibration means for main pipe for supplying water (605) and backwater supervisor (606) allow water circulation, the round rails of outer three circle for windmill another set of vibration means for main pipe for supplying water (605) and backwater be responsible for (606) and allow water circulation, can carry out the conversion of high pressure, low-pressure water circulation by controlling the switch of water main valve, thereby in conversion, the three reversible working oil hydraulic pumps (601) that enclose circle rail windmills or outer three circle circle rail windmills are outputting powers or power are provided, when water main valve (604-1,604-3,604-5,604-7) is closed, water main valve (604-2,604-4,604-6,604-8) is opened, while allowing vibration means for main pipe for supplying water (605) connect high-pressure gas pressure tank (613), backwater supervisor (606) connection circulating water pool (609), reversible working oil hydraulic pump (601) utilizes water circulation outputting power to generate electricity by generator, when water main valve (604-1,604-3,604-6,604-8) is closed, water main valve (604-2,604-4,604-5,604-7) is opened, switch wherein a set of vibration means for main pipe for supplying water (605) and connect circulating water pool (609), backwater supervisor (606) connection high-pressure gas pressure tank (613), can make this three one group of reversible working oil hydraulic pump (601) that encloses circle rail windmill utilize water circulation to obtain power and allow windmill against the wind turn round, when water main valve (604-2,604-4,604-5,604-7) is closed, water main valve (604-1,604-3,604-6,604-8) is opened, one group of reversible working oil hydraulic pump (601) of changeable other three circle circle rail windmills utilizes water circulation acquisition power to allow windmill against the wind turn round, measure mobile round rail windmill car body (3) and circular windmill track (4) relative bearing of fixing by setting party's position measuring sensor, again by Remote Automatic Control System (1) according to azimuthal measurement sensor information, controlling the gear (404) of vertical shaft engages or disconnects with the upper engaging and disengaging gear of vertical shaft (406) between reversible working oil hydraulic pump (601), reversible working oil hydraulic pump (601) and oil hydraulic pump water inlet pipe (602), aqueduct valve (607) switch of oil hydraulic pump outlet pipe (603), regulate the quantity of the reversible working oil hydraulic pump (601) of operation in parallel, reversible working oil hydraulic pump (601) by regulating operation in parallel quantity of the reversible working oil hydraulic pump (601) of operation on every circle on three circles circle rails, thereby regulate resistance or the power of every circle circle rail windmill car body (3), make three circle circle rail windmill car body (3) operations keep synchronous.
Next illustrate that oil hydraulic pump and hydraulic tube transmission device make three circle circle rail windmill car body (3) operations keep the working principle of synchronous operation to windmill car body operation fine setting: the gear (404) of the vertical shaft of circular windmill track regulates drive wheel to be connected by vertical shaft (406) and orientation and drives reversible working oil hydraulic pump to rotate, a closed loop hydraulic tube is across two reversible working oil hydraulic pumps of two circle circle rail series connection, a regulation and control oil hydraulic pump in parallel again, thereby the fluid flow of regulation and control oil hydraulic pump in can bidirectional modulation hydraulic tube changes the rotating ratio of two reversible working oil hydraulic pumps of series connection, this oil hydraulic pump vernier device arranges many groups by being equidistantly arranged between round rail, measure the relative bearing of two mobile circle circle rail windmill car bodies (3) by setting party's position measuring sensor, again by Remote Automatic Control System (1) according to azimuthal measurement sensor information, regulate the rotating ratio of two reversible working oil hydraulic pumps of connecting in each group, thereby regulate resistance or the power of two circle circle rail windmill car bodies (3), make three circle circle rail windmill car body (3) operations keep synchronous.
Next hydraulic generator unit (616) working principle is described: hydraulic generator unit (616) has multiple intelligent combination by series and parallel, motor aqueduct valve (619) is controlled to open by Remote Automatic Control System (1) and is made high-pressure water flow rush at fast hydraulic turbine generator, makes hydraulic generator unit (616) complete different capacity output procedure by various combination; Hydraulic generator unit (616) is connected between motor outlet pipe (618) and motor water inlet pipe (614), be arranged in parallel earth pressure release water recovery apparatus with generator set----reflow pipe and unidirectional Self controlling valve (615), in the time of generator set removal of load, high-pressure water flow can flow through from reflow pipe from a hydraulic turbine generator shunting part; Hydraulic pressure energy collecting multicomputer power generation system (6) can convert the kinetic pressure in energy circulation system and device to electric energy, is connected to the grid by electric power handling cable (617).
Air pressure energy collecting multicomputer power generation system (7) is arranged between Nei Sanquan and outer three circle circle rail windmills, organizes air pressure energy collecting multicomputer power generation system (7) more and arranges by equidistant circumference along circle rail windmill track one side; As shown in Figure 7, every group of air pressure energy collecting multicomputer power generation system (7) comprises reversible working air pump (701), air pressure adjustment valve (702), air feed supervisor (703), return-air supervisor (704), air pump suction tude (705), air pump discharge pipe (706), tracheae valve (707), turbo-generator group (709), motor suction tude (710), motor row tracheae (711), low pressure gasholder (712), high pressure tank (713), motor tracheae valve (714); Its medium transmitting in the circulatory system for transformation of energy is air, is applicable to extremely frigid zones; Pressurized gas in high pressure tank (713) convert to after electric energy by motor suction tude (710) access turbo-generator group (709) generating, and gas is recycled to low pressure gasholder (712) along motor row tracheae (711); The bottom of circular windmill track (4) is installed with reversible working air pump (701), and reversible working air pump (701) is mechanical energy can be converted to the pressure energy of gas, also the pressure energy of gas can be converted to mechanical energy; Each reversible working air pump (701) respectively with air pump suction tude (705), airtight connection of air pump discharge pipe (706) that tracheae valve (707) is installed, many air pump suction tude (705) are parallel to air feed supervisor (703), and many air pump discharge pipes (706) are parallel to return-air supervisor (704); Air feed supervisor (703), return-air supervisor (704) extend along circular windmill track (4), several reversible working air pumps in parallel (701).
Next the working principle of air pressure energy collecting multicomputer power generation system (7) regulation and control windmill car body synchronous operation is described: a set of air feed of interior three circle circle rail windmill of every group of air pressure energy collecting multicomputer power generation system (7) be responsible for (703), return-air supervisor (704) and allowed gas circulation, the another set of air feed of the round rail windmill of outer three circle be responsible for (703), return-air to be responsible for (704) and to allow gas circulation; Can carry out the conversion of high pressure, low-pressure gas circulation by controlling the switch of main tracheae valve, thereby in conversion, the three reversible working air pumps (701) that enclose circle rail windmills or outer three circle circle rail windmills are outputting powers or power are provided; When main tracheae valve (708-1,708-3,708-5,708-7) is closed, main tracheae valve (708-2,708-4,708-6,708-8) is opened, while allowing air feed supervisor (703) connect high pressure tank (713), return-air supervisor (704) connection low pressure gasholder (712), reversible working air pump (701) utilizes gas circulation outputting power to generate electricity by generator; When main tracheae valve (708-1,708-3,708-6,708-8) is closed, main tracheae valve (708-2,708-4,708-5,708-7) is opened, switch wherein a set of air feed supervisor (703) connection low pressure gasholder (712), return-air supervisor (704) connection high pressure tanks (713), can make one group of reversible working air pump (701) of this three circles circle rail windmill utilize gas circulation acquisition power to allow windmill against the wind turn round; When main tracheae valve (708-2,708-4,708-5,708-7) is closed, main tracheae valve (708-1,708-3,708-6,708-8) is opened, one group of reversible working air pump (701) of changeable other three circle circle rail windmills utilizes gas circulation acquisition power to allow windmill against the wind turn round.Measure mobile round rail windmill car body (3) and circular windmill track (4) relative bearing of fixing by setting party's position measuring sensor, again by Remote Automatic Control System (1) according to azimuthal measurement sensor information, controlling the gear (404) of vertical shaft engages or disconnects with the upper clutch device (407) of vertical shaft (406) between reversible working air pump (701), control reversible working air pump (701) and air pump suction tude (705), tracheae valve (707) switch of air pump discharge pipe (706), regulate the quantity of the reversible working air pump (701) of operation in parallel, thereby regulate resistance or the power of every circle circle rail windmill car body (3), make three circle circle rail windmill car body (3) operations keep synchronous.
Next turbo-generator group (709) working principle in air pressure energy collecting multicomputer power generation system (7) is described: in the time that air pressure reaches specified value, motor tracheae valve (714) is controlled to open by Remote Automatic Control System (1) and made high-pressure gas blow to fast turbo-generator group (709); Turbo-generator group (709) has multiple intelligent combination by series and parallel, can complete generator different capacity output procedure; Be provided with the air pressure adjustment valve (702) that can exchange with ambient atmos at low pressure gasholder (712), when tank internal air pressure during lower than ambient pressure air pressure adjustment valve (702) automatically open air inlet, when tank internal air pressure during higher than ambient pressure air pressure adjustment valve automatically close, confined gas is circulated and is kept above extraneous certain air pressure; Air pressure energy collecting multicomputer power generation system (7) can convert the kinetic pressure in energy circulation system and device to electric energy, is connected to the grid by electric power handling cable (617).
As shown in Figure 9, there are upper race (502) and lower railway (501) in circular drag-line Car Track one side, there is middle race (503) at middle part above, and side drive gear (508) and side auxiliary drive circle wheel (509) are installed in track, supporting wheel (505), lower support wheel (506), horizontal support wheel (507) are installed on drag-line car siding track (504), the outside of described round rail disjunctor drag-line car siding track (504) is provided with tooth bar fixed groove and is meshed with side drive gear (508), the inner side of described drag-line car siding track is that plate rail engages with side auxiliary drive circle wheel (509), makes drag-line car siding track (504) engage very close to each other with side drive gear (508) and side auxiliary drive circle wheel (509), the upper supporting wheel (505) of described round rail disjunctor drag-line car heads on race (502), lower support wheel (506) is being pressed lower railway (501), horizontal support wheel (507) concora crush middle race (503), horizontal support wheel axis is vertically mounted on drag-line car siding track (504), suspension cable (209) is arranged on horizontal support wheel axis top, circle rail disjunctor drag-line car (5) is connected with middle Y-shaped compound leaf sheet (2) by suspension cable (209), make circle rail disjunctor drag-line car (5) can bear suspension cable (209) pulling force and not derail along circular drag-line Car Track operation all the time, circular drag-line Car Track is by installation side actuation gear (508) and the side auxiliary drive circle wheel (509) of equidistantly arranging, and side drive gear (508) drives circle rail disjunctor drag-line car (5) to rotate.
The operation of circle rail disjunctor drag-line car (5) will keep same angular velocity operation with circle rail windmill, can select two kinds of modes to combine transmission: mode one hydraulic transmission, vertical shaft (510) is set up variable speed controllable oil hydraulic motor (512), variable speed controllable oil hydraulic motor (512) is connected with high-pressure gas pressure tank (613), circulating water pool (609) by water pipe, variable speed controllable oil hydraulic motor (512) to side drive gear (508), makes circle rail disjunctor drag-line car (5) operation as power source transmission; Mode two Electrified Transmission, actuating motor (511) makes circle rail disjunctor drag-line car (5) operation as power source driving side actuation gear (508); Circle rail disjunctor drag-line car (5) and circle rail windmill car body (3) setting party's position measuring sensor, by Remote Automatic Control System (1) according to azimuthal measurement sensing data, automatically regulate the rotating speed of transmission to side drive gear (508), make the relative bearing Deviation Control of circle rail disjunctor drag-line car (5) and circle rail windmill car body (3) in allowed band.
Next how explanation solves the impact of expanding with heat and contract with cold on windmill girth, circle rail windmill car body (3) joins end to end, in two round equal branches or four equal branches, controllable moving joint is set, so that circle rail windmill car body (3) girth after expanding with heat and contract with cold remains unchanged, as shown in Fig. 5-2, controllable moving joint connecting means between two compound leaf sheets: mast (201-2) and side mast (201-9) on the upper middle circle rail of circle rail windmill car body (3), both sides circle rail upside mast (202-5) and side mast (202-6), side mast (202-7) is connected by mast connecting rod with side mast (202-8), by Remote Automatic Control System control driven by servomotor spiral propeller, spiral propeller promotes mast connecting rod and shortens or extend, mast connecting rod synchronously shortens prolongation with circle rail windmill car body active connection place, between two compound leaf sheets, by vertical pulling rope (208), the side compound leaf face (20302) between the circle rail of both sides is connected with horizontal support post (207) substantially horizontal perpendicular to mast (201-1), hinge sees through the sliding bar that hollow horizontal support post (207) center connects its inside, sliding bar relies on connection for transmission chain to reciprocatingly slide in hollow horizontal support post (207), Transmitted chains provides power transmission by Remote Automatic Control System control actuating motor, regulate sliding bar sliding distance, sliding bar is installed clutch locking device, moving into place can be locked motionless, to regulate vertical pulling rope (208) length synchronously to shorten prolongation with circle rail windmill car body active connection place, circle rail windmill car body (3) controllable moving joint connecting means: with the car body connecting rod connection that can extend and can retract, car body siding track (301) will keep uninterrupted connection, make gear (404), the circle wheel (405) of vertical shaft continue to engage running, by Remote Automatic Control System control driven by servomotor spiral propeller, spiral propeller promotes car body connecting rod and shortens or extend, and regulates circle rail windmill car body (3) length, circle rail disjunctor drag-line car (5) controllable moving joint connecting means: with the car body connecting rod connection that can extend and can retract, by Remote Automatic Control System control driven by servomotor spiral propeller, spiral propeller promotes drag-line car car body connecting rod and shortens or extend, and regulates circle rail disjunctor drag-line car (5) length synchronously to shorten prolongation with circle rail windmill car body active connection place.
Next how explanation solves the impact across three circle circle rails on windmill of expanding with heat and contract with cold, the mast (201) of Y-shaped compound leaf sheet (2), single blade central shaft adopt the large material of coefficient of thermal expansion and contraction, and grid framework (204), grid framework supporting frame (205) adopt the little material of coefficient of thermal expansion and contraction, heat up and cause that grid framework (204) is drawn high, offset its horizontal heat expansion and change, expand with heat and contract with cold can cause compound leaf sheet variable height, it can not change across span; And the material that the compound leaf sheet blade face that on three circle circle rails, centre circle circle rail bearing carries adopts, its size of expanding with heat and contract with cold will be consistent with circle rail windmill car body (3).
As shown in Figure 1, circle rail windmill car body (3) has six circles, and Y-shaped compound leaf sheet (2) opening angle of interior three circle circle rail windmill car body (3) carryings is contrary with Y-shaped compound leaf sheet (2) opening angle of outer three circle circle rail windmill car body (3) carryings; Circular drag-line Car Track has four circles, above circular drag-line Car Track, moving and justifying rail disjunctor drag-line car (5), every two circle circle rail disjunctor drag-line cars (5) are connected with middle Y-shaped compound leaf sheet (2) by suspension cable (209); But be not limited to this, circle rail windmill car body (3) can have 6 circles, more than 12 circles, circle rail disjunctor drag-line car (5) can have 4 circles, more than 8 circles, and each loop diameter is descending, large snare ringlet; Circle rail windmill car body (3) and circle rail disjunctor drag-line car (5) can join end to end, and also can disconnect and being divided into more than 2 sections or 2 sections, do not contact mutually and orbiting between each section, expand with heat and contract with cold and cause that windmill perimeter change can adapt to automatically.

Claims (19)

1. one kind two-wayly carries the multiple blade fluid energy collecting multicomputer wind motor for electric generation of Y-shaped to turning round rail bearing, it is characterized in that, comprise the Y-shaped compound leaf sheet (2) that single blade combines, the round rail windmill car body (3) of carrying Y-shaped compound leaf sheet (2), the circular windmill track (4) of carrying circle rail windmill car body (3) operation, draw the round rail disjunctor drag-line car (5) moving of round rail windmill on circular drag-line Car Track with suspension cable (209) Dou, hydraulic pressure energy collecting multicomputer power generation system (6) or air pressure energy collecting multicomputer power generation system (7), wherein
Described Y-shaped compound leaf sheet (2) is by three circle circle rail windmill car body (3) carryings, by being equidistantly arranged in successively on round rail windmill car body (3);
Described round rail windmill car body (3) has six circles, Y-shaped compound leaf sheet (2) opening angle of Y-shaped compound leaf sheet (2) opening angles of interior three circle circle rail windmill car bodies (3) carryings and the outer three round rail windmill car bodies of circle (3) carryings is contrary, makes circle rail windmill two-way to turning;
Described circular drag-line Car Track has four circles, above circular drag-line Car Track, moving and justifying rail disjunctor drag-line car (5), every two circle circle rail disjunctor drag-line cars (5) are connected with middle Y-shaped compound leaf sheet (2) by suspension cable (209).
2. one according to claim 1 is two-way carries the multiple blade fluid energy collecting multicomputer wind motor for electric generation of Y-shaped to turning round rail bearing, it is characterized in that, compound leaf face (20301), two the side compound leaf faces in left and right (20302) in the middle of described Y-shaped compound leaf sheet (2) comprises, between three faces, angle 120 is spent, equal in length, overlook and be Y-shaped; The side that the top of side compound leaf face (20302) is provided with the miter angle that the leans forward compound leaf face (20303) that leans forward; Compound leaf face is by transferring perpendicular to ground the miter angle that turns forward to.
3. one according to claim 2 is two-way carries the multiple blade fluid energy collecting multicomputer wind motor for electric generation of Y-shaped to turning round rail bearing, it is characterized in that, the compound leaf face of described Y-shaped compound leaf sheet (2) is by grid framework (204), single blade and mast combine, described grid framework (204) is by laterally multiple, the grid composition of upper and lower multilayer, fixing rhombus list blade (212) is installed in the grid of described grid framework (204), the single blade (211) rotating around mast, pentagon list blade, triangle list blade (213), polygonal disjunctor blade (216).
4. one according to claim 3 is two-way carries the multiple blade fluid energy collecting multicomputer wind motor for electric generation of Y-shaped to turning round rail bearing, it is characterized in that, described rhombus list blade (212) is combined by single blade axis of rotation (21202), single blade rack bar (21203), single blade frame (21204), blade reinforcement rope (21205), blade surface (21201), single blade supporting post (21206), single blade tow rope (21207), single blade axis of rotation gear (21208);
The axis of rotation of single blade is fixedly connected with single blade frame (21204), in single blade frame (21204), be provided with single blade rack bar (21203), described single blade supporting post (21206) is vertically fixedly connected with the blade axis of rotation (21202) through blade center, single blade supporting post (21206) is by many single blade tow ropes (21207) and single blade frame (21204), single blade rack bar (21203), the blade axis of rotation (21202) is fixedly connected, single blade tow rope (21207) is symmetrical in leave dual sides.
5. one according to claim 1 is two-way carries the multiple blade fluid energy collecting multicomputer wind motor for electric generation of Y-shaped to turning round rail bearing, it is characterized in that, between described single blade, be provided with wind device for regulating direction, the endless drive chain (21109) in wind device for regulating direction connected to multiple single blades and form one group of composition linkage list blade.
6. one according to claim 1 is two-way carries the multiple blade fluid energy collecting multicomputer wind motor for electric generation of Y-shaped to turning round rail bearing, it is characterized in that, there are lower railway (401) and upper race (402) in circular windmill track (4) bi-side of described carrying circle rail windmill car body operation, middle part has middle race (403), inside that gear (404) and the circle wheel (405) of vertical shaft are installed above; Described round rail windmill car body (3) both sides are installed with lower wheel (302) and upper wheel (303) are installed on car body siding track (301), siding track, in the middle of being installed with above car body, left wheel (304), middle right wheel (305), is carrying oil hydraulic pump (306) or pneumatic pump (307), actuating motor (308), Y-shaped compound leaf sheet (2); The outside of described windmill car body siding track (301) is provided with tooth bar fixed groove and is meshed with the gear (404) of vertical shaft; The inner side of described windmill car body siding track (301) is that plate rail engages with circle wheel (405), on upper wheel (303), head on race (402), lower wheel (302) is pressing down lower railway (401), and middle left wheel (304), middle right wheel (305) are to race (403) in sandwich.
7. according to claim 1, 3, one described in 5 or 6 is two-way carries the multiple blade fluid energy collecting multicomputer wind motor for electric generation of Y-shaped to turning round rail bearing, it is characterized in that, the mast (201) of described compound leaf sheet is hollow cylinder, inside is provided with oil pipe (309), speed change control motor apparatus (21110), a gas storage pressure tank (311) is installed under each mast (201), one group of series-parallel oil hydraulic pump (306), multiple oil hydraulic pumps (306) by with each on wheel (303) be connected, the rotation of upper wheel (303) makes oil hydraulic pump (306) pressurization form high-voltage drive liquid and comes and goes operation along oil pipe (309) circulation, Energy transfer is arrived to the speed change control motor apparatus (21110) in mast (201), for composition linkage list blade provides power, the oil hydraulic pump (306) of an actuating motor (308) and its driving is installed in mast (201) bottom, when windmill reaches startup wind speed, and single blade is need to be to wind tuning time, start actuating motor (308), drive oil hydraulic pump (306) to make transmission fluid circulation transmission, switch to and provide power tuning by upper wheel (303) rotating drive oil hydraulic pump (306) so that all single blades, to wind tuning, are closed actuating motor (308) after windmill rotation,
At extremely frigid zones, the oil hydraulic pump (306) on circle rail windmill car body (3) is used pneumatic pump (307) instead; A gas holder (312), one group of series-parallel pneumatic pump (307) are installed under each mast (201), multiple pneumatic pumps (307) by with each on wheel (303) be connected, the rotation of upper wheel (303) makes pneumatic pump (307) pressurization form pressurized gas and is transported to gas holder (312), gas holder (312) connects the interior tracheae of mast (201) (310), and Energy transfer is upper to the speed change control motor apparatus (21110) in mast (201), for composition linkage list blade provides power; Start wind speed and gas holder (312) air pressure when not enough when windmill reaches, starting driven by servomotor pneumatic pump (307) be that gas holder (312) aerating is pressurizeed.
8. one according to claim 1 is two-way carries the multiple blade fluid energy collecting multicomputer wind motor for electric generation of Y-shaped to turning round rail bearing, it is characterized in that, on the ground at described circular windmill track (4) place by reversible working oil hydraulic pump (601) or reversible working air pump (701) are equidistantly installed successively; The gear (404) of the each group of vertical shaft of installing in circular windmill track (4) and circle wheel (405) clip windmill car body siding track (301), the gear (404) of each vertical shaft respectively connects a ground reversible working oil hydraulic pump (601) or reversible working air pump (701) by vertical shaft (406), is settling clutch device (407) on vertical shaft (406).
9. one according to claim 1 is two-way carries the multiple blade fluid energy collecting multicomputer wind motor for electric generation of Y-shaped to turning round rail bearing, it is characterized in that, described round rail windmill car body (3) joins end to end, and in two round equal branches or four equal branches, controllable moving joint is set.
10. one according to claim 1 is two-way carries the multiple blade fluid energy collecting multicomputer wind motor for electric generation of Y-shaped to turning round rail bearing, it is characterized in that, described hydraulic pressure energy collecting multicomputer power generation system (6) is arranged between Nei Sanquan and outer three circle circle rail windmills, respectively organizes hydraulic pressure energy collecting multicomputer power generation system (6) and arranges by equidistant circumference along circle rail windmill track one side; Every group of hydraulic pressure energy collecting multicomputer power generation system (6) comprises reversible working oil hydraulic pump (601), oil hydraulic pump water inlet pipe (602), oil hydraulic pump outlet pipe (603), backwater supervisor (606), vibration means for main pipe for supplying water (605), aqueduct valve (607), high-pressure gas pressure tank (613), air compressor (612), circulating water pool (609), pump for adding liquid (608), hydraulic generator unit (616), wherein
The medium that described hydraulic pressure energy collecting multicomputer power generation system (6) is transmitted in the circulatory system for transformation of energy is water, is applicable to long-term non-icing area;
High-pressure hydraulic in described high-pressure gas pressure tank (613) converts to after electric energy by motor water inlet pipe (614) access hydraulic generator unit (616) generating, and water flows to circulating water pool (609) along motor outlet pipe (618);
Described circulating water pool (609) T is connected to filler pipe, water valve, pump for adding liquid (608), can add water;
The interior gas of described high-pressure gas pressure tank (613) can keep larger volumetric spaces, reduce system liquid pressure water hammer under certain pressure, the upper T of high-pressure gas pressure tank (613) is connected with tracheal pressure (610), air valve (611), air compressor (612), can regulate the volumetric spaces ratio of the interior gas of high-pressure gas pressure tank (613) and water;
The bottom of described circular windmill track (4) is installed with reversible working oil hydraulic pump (601), each reversible working oil hydraulic pump (601) respectively with oil hydraulic pump water inlet pipe (602), airtight connection of oil hydraulic pump outlet pipe (603) that aqueduct valve (607) is installed, many oil hydraulic pump water inlet pipes (602) are parallel to vibration means for main pipe for supplying water (605), and many oil hydraulic pump outlet pipes (603) are parallel to backwater supervisor (606); Vibration means for main pipe for supplying water (605), backwater supervisor (606) extend along circular windmill track (4), several reversible working oil hydraulic pumps in parallel (601).
11. one according to claim 10 are two-way carries the multiple blade fluid energy collecting multicomputer wind motor for electric generation of Y-shaped to turning round rail bearing, it is characterized in that, described hydraulic pressure energy collecting multicomputer power generation system (6), the interior three circle circle rails of every group of hydraulic pressure energy collecting multicomputer power generation system (6) windmill for a set of vibration means for main pipe for supplying water (605) and backwater supervisor (606) allow water circulation, the round rails of outer three circle for windmill another set of vibration means for main pipe for supplying water (605) and backwater be responsible for (606) and allow water circulation; Can carry out the conversion of high pressure, low-pressure water circulation by controlling the switch of water main valve, thereby in conversion, the three reversible working oil hydraulic pumps (601) that enclose circle rail windmills or outer three circle circle rail windmills are outputting powers or power are provided.
12. one according to claim 10 are two-way carries the multiple blade fluid energy collecting multicomputer wind motor for electric generation of Y-shaped to turning round rail bearing, having oil hydraulic pump and hydraulic tube transmission device makes three circle circle rail windmill car body (3) operations keep synchronous operation to windmill car body operation fine setting, it is characterized in that, the gear (404) of the vertical shaft of circular windmill track is connected and is driven a reversible working oil hydraulic pump to rotate by vertical shaft (406), a closed loop hydraulic tube is across two reversible working oil hydraulic pumps of two circle circle rail series connection, a regulation and control oil hydraulic pump in parallel again, thereby the fluid flow of regulation and control oil hydraulic pump in can bidirectional modulation hydraulic tube changes the rotating ratio of two reversible working oil hydraulic pumps of series connection, this oil hydraulic pump vernier device arranges many groups by being equidistantly arranged between two circle circle rails.
13. one according to claim 10 are two-way carries the multiple blade fluid energy collecting multicomputer wind motor for electric generation of Y-shaped to turning round rail bearing, it is characterized in that, described hydraulic pressure energy collecting multicomputer power generation system (6), hydraulic generator unit (616) has multiple intelligent combination by series and parallel, motor aqueduct valve (619) is opened in control makes high-pressure water flow rush at fast hydraulic turbine generator, makes hydraulic generator unit (616) complete different capacity output procedure by various combination; Hydraulic generator unit (616) is connected between motor outlet pipe (618) and motor water inlet pipe (614), be arranged in parallel earth pressure release water recovery apparatus with generator set----reflow pipe and unidirectional Self controlling valve (615), in the time of generator set removal of load, high-pressure water flow can flow through from reflow pipe from a hydraulic turbine generator shunting part; Hydraulic pressure energy collecting multicomputer power generation system (6) can convert the kinetic pressure in energy circulation system and device to electric energy, is connected to the grid by electric power handling cable (617).
14. one according to claim 1 are two-way carries the multiple blade fluid energy collecting multicomputer wind motor for electric generation of Y-shaped to turning round rail bearing, it is characterized in that, described air pressure energy collecting multicomputer power generation system (7) is arranged between Nei Sanquan and outer three circle circle rail windmills, organizes air pressure energy collecting multicomputer power generation system (7) more and arranges by equidistant circumference along circle rail windmill track one side; Every group of air pressure energy collecting multicomputer power generation system (7) comprises reversible working air pump (701), air pressure adjustment valve (702), air feed supervisor (703), return-air supervisor (704), air pump suction tude (705), air pump discharge pipe (706), tracheae valve (707), turbo-generator group (709), motor suction tude (710), motor row tracheae (711), low pressure gasholder (712), high pressure tank (713), motor tracheae valve (714), wherein
The medium that described air pressure energy collecting multicomputer power generation system (7) is transmitted in the circulatory system for transformation of energy is air, is applicable to extremely frigid zones;
Pressurized gas in described high pressure tank (713) convert to after electric energy by motor suction tude (710) access turbo-generator group (709) generating, and gas is recycled to low pressure gasholder (712) along motor row tracheae (711);
The bottom of described circular windmill track (4) is installed with reversible working air pump (701), each reversible working air pump (701) respectively with air pump suction tude (705), airtight connection of air pump discharge pipe (706) that tracheae valve (707) is installed, many air pump suction tude (705) are parallel to air feed supervisor (703), and many air pump discharge pipes (706) are parallel to return-air supervisor (704); Air feed supervisor (703), return-air supervisor (704) extend along circular windmill track (4), several reversible working air pumps in parallel (701).
15. one according to claim 14 are two-way carries the multiple blade fluid energy collecting multicomputer wind motor for electric generation of Y-shaped to turning round rail bearing, it is characterized in that, described air pressure energy collecting multicomputer power generation system (7), the interior three circle circle rail windmills of every group of air pressure energy collecting multicomputer power generation system (7) be responsible fors (703), return-air supervisor (704) with a set of air feed and are allowed gas circulation, the another set of air feed of the round rail windmill of outer three circle be responsible for (703), return-air to be responsible for (704) and to allow gas circulation; Can carry out the conversion of high pressure, low-pressure gas circulation by controlling the switch of main tracheae valve, thereby in conversion, the three reversible working air pumps (701) that enclose circle rail windmills or outer three circle circle rail windmills are outputting powers or power are provided.
16. one according to claim 14 are two-way carries the multiple blade fluid energy collecting multicomputer wind motor for electric generation of Y-shaped to turning round rail bearing, it is characterized in that, described air pressure energy collecting multicomputer power generation system (7), in the time that high pressure tank (713) air pressure reaches specified value, motor tracheae valve (714) is opened in control makes high-pressure gas blow to fast turbo-generator group (709); Turbo-generator group (709) has multiple intelligent combination by series and parallel, can complete generator different capacity output procedure; Be provided with the air pressure adjustment valve (702) that can exchange with ambient atmos at low pressure gasholder (712), when tank internal air pressure during lower than ambient pressure air pressure adjustment valve (702) automatically open air inlet, when tank internal air pressure reach or during higher than ambient pressure air pressure adjustment valve automatically close, confined gas is circulated and is kept above extraneous certain air pressure; Air pressure energy collecting multicomputer power generation system (7) can convert the kinetic pressure in energy circulation system and device to electric energy, is connected to the grid by electric power handling cable (617).
17. one according to claim 1 are two-way carries the multiple blade fluid energy collecting multicomputer wind motor for electric generation of Y-shaped to turning round rail bearing, it is characterized in that, there are upper race (502) and lower railway (501) in described circular drag-line Car Track one side, there is middle race (503) at middle part above, side drive gear (508) and side auxiliary drive circle wheel (509) are installed in track, supporting wheel (505), lower support wheel (506), horizontal support wheel (507) are installed, wherein on drag-line car siding track (504)
The outside of described round rail disjunctor drag-line car siding track (504) is provided with tooth bar fixed groove and is meshed with side drive gear (508); The inner side of described drag-line car siding track is that plate rail engages with side auxiliary drive circle wheel (509);
The upper supporting wheel (505) of described round rail disjunctor drag-line car heads on race (502), lower support wheel (506) is being pressed lower railway (501), horizontal support wheel (507) concora crush middle race (503), horizontal support wheel axis is vertically mounted on drag-line car siding track (504), suspension cable (209) is arranged on horizontal support wheel axis top, and circle rail disjunctor drag-line car (5) is connected with middle Y-shaped compound leaf sheet (2) by suspension cable (209);
Described circular drag-line Car Track is by installation side actuation gear (508) and the side auxiliary drive circle wheel (509) of equidistantly arranging, and side drive gear (508) drives circle rail disjunctor drag-line car (5) to rotate.
18. one according to claim 17 are two-way carries the multiple blade fluid energy collecting multicomputer wind motor for electric generation of Y-shaped to turning round rail bearing, it is characterized in that, the operation of circle rail disjunctor drag-line car (5) will keep same angular velocity operation with circle rail windmill, can select two kinds of modes to combine transmission: mode one hydraulic transmission, vertical shaft (510) is set up variable speed controllable oil hydraulic motor (512), variable speed controllable oil hydraulic motor (512) is by water pipe and high-pressure gas pressure tank (613), circulating water pool (609) is connected, variable speed controllable oil hydraulic motor (512) as power source transmission to side drive gear (508), make circle rail disjunctor drag-line car (5) operation, mode two Electrified Transmission, actuating motor (511) makes circle rail disjunctor drag-line car (5) operation as power source driving side actuation gear (508), circle rail disjunctor drag-line car (5) and circle rail windmill car body (3) setting party's position measuring sensor, according to azimuthal measurement sensing data, regulate the rotating speed of transmission to side drive gear (508), make circle rail disjunctor drag-line car (5) and the relative bearing of circle rail windmill car body (3) keep fixing.
19. one according to claim 17 are two-way carries the multiple blade fluid energy collecting multicomputer wind motor for electric generation of Y-shaped to turning round rail bearing, it is characterized in that, described round rail disjunctor drag-line car (5) joins end to end, and in two equal branches of circumference or four equal branches, controllable moving joint is set.
CN201420104079.8U 2014-03-10 2014-03-10 Two-way contra-rotating round rail carrying Y-shaped multi-blade fluid energy collecting multi-unit power generating windmill Expired - Fee Related CN203906183U (en)

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Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN107687396A (en) * 2017-08-17 2018-02-13 刘海龙 Track carrying compound leaf piece back and forth runs multicomputer power generation windmill and tuning method

Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN107687396A (en) * 2017-08-17 2018-02-13 刘海龙 Track carrying compound leaf piece back and forth runs multicomputer power generation windmill and tuning method
CN107687396B (en) * 2017-08-17 2019-10-18 刘海龙 Track carrying compound leaf piece back and forth runs multicomputer power generation windmill and tuning method

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