CN219220625U - Matrix frame vertical shaft wind power down-transmission horizontal shaft distribution type wind driven generator - Google Patents

Abstract

The utility model relates to a distributed wind driven generator with a matrix frame and vertical shafts and a horizontal shaft. The wind driven generator is characterized in that: matrix frame, vertical scroll, wind-force are transferred down, and generating set falls to ground. The overall structure is that a matrix grid structure is used as a frame, the frame is an assembled assembly, and the wind wheel systems are densely arranged in the frame. When wind power is generated, wind power is transmitted to the transverse shaft transmission system, and is distributed to the generator set according to the combined transmission size of the wind power, so that the intelligent automatic control can be realized, unstable wind power can be generated by adopting adaptability and selective proportioning, and the wind power can be reasonably allocated and utilized. The parts of the wind driven generator are of a miniaturized, modularized and assembled structure, and the generator set is easy to be large and small and suitable for various choices. Easy to install and transport, is not limited by the topography and is particularly suitable for being built on mountainous regions and peak tops with complex topography.

Description

Matrix frame vertical shaft wind power down-transmission horizontal shaft distribution type wind driven generator

Technical Field

The utility model relates to the technical field of new energy power generation, in particular to a distributed wind driven generator with a matrix frame and vertical shafts transmitting wind power downwards to a transverse shaft.

Background

In recent years, wind driven generators are rapidly developed, the single machine is manufactured to be larger and larger, the wind driven generators are more and larger, impellers, cabins and supports are all large, the cabins are unstable on the high supports, and the barrel bodies of the supports are easy to fatigue and influence the strength. In the construction and installation process, special large-scale transportation and lifting vehicles are needed, and large-scale equipment is more difficult to run on the ground without roads and on rugged ground. Therefore, it is difficult to build the wind power generator in mountain land with rich wind sources, so that the site selection of the wind power plant is limited, and the optimal wind energy position cannot be obtained, thereby influencing the power generation efficiency.

The wind driven generator generates electricity by wind energy, and places with rich wind sources are generally selected for site selection. The most abundant place on land is mountain land, and the higher the mountain land is, the more abundant the wind resource is. However, the mountain wind power plant has complex terrain conditions and relatively few available areas, so that the wind power generator tends to be large-sized, the mountain wind power plant is not beneficial to selection, and the wind energy resources rich in mountain areas cannot be better utilized. The efficient utilization of wind energy resources is the first choice for building a wind farm, and the larger the structural part of the wind driven generator is, the more difficult the wind farm is to select sites. How to make the wind driven generator into a small-part modularized easy-assembly structure is more beneficial to selecting regions with rich wind energy resources and can reasonably allocate and utilize the wind energy resources, and becomes a problem to be solved urgently in the technical field of new energy power generation at present.

Disclosure of Invention

In order to solve the technical problems in the prior art, it is necessary to provide a matrix frame vertical shaft wind power down-transmission horizontal shaft distribution type wind driven generator. A matrix frame vertical axis wind down to horizontal axis distributed wind turbine, the wind turbine comprising: matrix grid frame, wind wheel vertical shaft group, cross axle transmission system, wind power distribution system, firm oblique support, wind power distribution system includes: the wind wheel vertical shaft group is arranged on the matrix-shaped grid frame, the transverse shaft transmission system is arranged on the matrix-shaped grid frame, the wind wheel vertical shaft group is connected with the transverse shaft transmission system, wind power is transmitted to the transverse shaft transmission system by the wind wheel vertical shaft group, the matrix-shaped grid frame is supported by the stable inclined support, the transverse shaft transmission system is connected with the generator set, the generator set is provided with an automatic control system, the automatic control system determines to start the number of the generator set according to the wind quantity, the electric sloping cam plate is connected with the wind wheel vertical shaft group, and the electric sloping cam plate adjusts the wind blades in the wind wheel vertical shaft group according to the wind direction and the wind quantity.

Preferably, the matrix-shaped grid framework is an assembly body, and the buckling piece is formed by the buckling plate and the corner seat and is used for connecting and assembling the transverse pipe and the vertical pipe.

Preferably, the wind wheel vertical shaft groups are longitudinally densely arranged in the matrix-shaped grid framework and are fixed on the transverse pipes layer by layer. Preferably, the transverse shaft transmission system is arranged at the lower end of the wind wheel vertical shaft group, and wind power transmitted by the wind wheel vertical shaft group is gathered on the transverse shaft transmission system.

Preferably, the electric pusher in the electric swash plate controls the pusher.

The wind power generator body is a matrix grid framework, the wind blades are densely distributed, the vertical shaft wind power is downwards transmitted and collected on one transverse shaft, the generators are grouped and landed, the wind power is generated by distributing the wind quantity, the structural parts are small in modular, the building blocks are favorable for assembling in complex terrains, the matrix grid framework is fully filled with wind wheels, the wind wheels are arranged in groups in the vertical shaft mode, all the vertical shafts are used for downwards transmitting and collecting the wind power of the wind wheels on one transverse shaft, the transverse shaft is connected with a plurality of generator sets in parallel, the generators are distributed according to the wind quantity, the generator sets are selectively and rarely or multiply opened, so that unstable wind sources are generated by matching and selectively proportioning, the wind power is reasonably allocated and utilized, the wind power is distributed, the generators are grouped, and the generator sets are landed.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present utility model, the drawings that are needed for the description of the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present utility model, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a front view of a matrix frame distributed wind generator with vertical axis wind down-load to the horizontal axis.

FIG. 2 is a left side view of a matrix frame distributed wind generator with vertical axis wind down-load to the horizontal axis.

FIG. 3 is a top view of a matrix frame vertical axis wind down-wind generator of the present utility model in a horizontal axis distribution.

FIG. 4 is a diagram showing a mode that the vertical shaft wind power of the matrix frame is transmitted to the wind driven generator with the distribution type of the horizontal shaft and is built on the peak top slope.

FIG. 5 is a grid frame diagram of a matrix frame of the utility model with vertical axis wind down-load to horizontal axis distributed wind turbines.

FIG. 6 is a cross-tube connection diagram of a matrix frame of the present utility model with vertical axis wind down-transfer to a cross-axis distributed wind turbine frame.

FIG. 7 is a view showing the connection of vertical pipes and vertical pipes of a matrix frame of the utility model to a horizontal-axis distributed wind turbine frame.

FIG. 8 is an enlarged view of a portion of a transmission system for a vertical axis wind power down-take to a horizontal axis distributed wind turbine in a matrix frame of the present utility model.

FIG. 9 is a diagram of a vertical axis wind turbine assembly of a matrix frame of the present utility model for wind down-drive to a horizontal axis distributed wind turbine.

FIG. 10 is a diagram of a rotor set of a matrix frame vertical axis wind turbine of the present utility model down-wind to horizontal axis distributed wind turbine.

FIG. 11 is a diagram showing the operation of the wind wheel of the distributed wind power generator with the vertical axis wind power transmitted down to the horizontal axis by the matrix frame according to the present utility model.

FIG. 12 is a view of a wind blade set of a distributed wind generator with a matrix frame vertical axis wind down-load to a horizontal axis.

FIG. 13 is a view of a blade set A-A of a distributed wind driven generator with a matrix frame for vertical axis wind power down-wind transmission to a horizontal axis.

FIG. 14 is a view showing the connection of the wind power down-stream to the wind power generator blade shaft of the horizontal-axis distributed wind power generator with the matrix frame according to the present utility model.

FIG. 15 is a graph showing the axial relationship of a rotor set of a matrix frame vertical axis wind turbine of the present utility model being driven down to a horizontal axis distributed wind turbine.

FIG. 16 is a view of the wind turbine B-B upper axle seat of the matrix frame of the present utility model with vertical axis wind down-transferred to the horizontal axis distribution type wind turbine.

FIG. 17 is a front view of a wind turbine mount of a matrix frame of the present utility model with vertical axis wind down-wind turbine mount of a horizontal axis distributed wind turbine.

FIG. 18 is a top view of a wind turbine mount of a matrix frame of the present utility model with vertical axis wind down to a horizontal axis distributed wind turbine.

FIG. 19 is a diagram showing the connection of the vertical shaft wind power transmission to the transmission control shaft in the lower shaft seat of the wind wheel set C of the horizontal-axis distributed wind driven generator.

FIG. 20 is a schematic diagram showing the general view of the motor swash plate of the wind power generator with the matrix frame and the vertical shaft wind power down-transferred to the horizontal shaft.

FIG. 21 is a view of a swashplate assembly of a matrix frame of the present utility model for vertical axis wind down-load to horizontal axis distributed wind turbine.

FIG. 22 is a top view of a swashplate assembly of a matrix frame of the present utility model for vertical axis wind down-drive to horizontal axis distributed wind turbine.

FIG. 23 is an enlarged view of D in the overall view of the swashplate of the matrix frame of the present utility model for wind down-load to the horizontal axis distributed wind turbine.

In the figure, the grid frame is 1-matrix, the vertical shaft group of 2-wind wheel, the 3-horizontal shaft transmission system, the 4-generator set, the 5-stable inclined support, the 6-electric inclined plate, the 7.1-7.3-generator room, the 8-inclined support, the 9-angle adjusting transmission box, the 10-horizontal pipe, the 11-vertical pipe, the 12-fastening piece, the 13-fastening plate, the 14-angle seat, the 15-bolt, the 16-two-output shaft right angle transmission box, the 17-three-output shaft parallel transmission box, the 18-four-output shaft rotation angle transmission box, the 19-short shaft, the 20.1-20.3-shaft seat, the 21-vertical shaft, the 22.1-22.3-wind wheel group, the 23.1-23.5-wind wheel, the 24.1-24.3-blade, the 25-wind blade, the 26-wind blade and the 27-rivet 28-fan blade shaft, 29-short shaft, 30-shaft nest, 31-coupler, 32-coupler, 34-shaft end, 35-bolt, 36-through shaft, 37-upper shaft seat, 38.1-38.5-fan wheel seat, 39-lower shaft seat, 40.1-40.3-push-pull shaft, 41.1-41.4-rotating sleeve, 42-shaft seat body, 43-outer solid, 44-shaft sleeve, 45-thrust bearing, 46-upper end cover, 47-bolt, 48-ball bearing, 49-lower end cover, 50-bolt, 51-short shaft sleeve, 52-flat key, 53-needle bearing, 54-ball bearing, 55-thrust bearing, 56-end cover, 57-bolt, 58-upper cover plate, 59-outer cylinder 60-hinge shaft, 61-connecting rod, 62-hinge shaft, 63-turntable, 64-bolt, 65-flat key, 66-rotating ball, 67-jackscrew, 68-ball bearing, 69-thrust bearing, 70-non-rotating tray, 71-hinge shaft, 72-control disc, 73-swing sleeve, 74-ball cage, 75-bolt, 76-lower arc sleeve, 77-gland, 78-bolt, 79-bolt, 80-bottom cover, 81-ball cover, 82-bolt, 83-ball cover, 84-sphere, 85-bolt, 86-motor cover, 87-electric push rod motor, 88-lifting push rod, 89-coupler, 90-bolt, 91-ball bearing, 92-bolt, 93-bolt, 94-bearing cover, 95-output shaft.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

A matrix frame vertical shaft wind power is transmitted to a horizontal shaft distribution type wind driven generator, and the overall structural characteristics are that: matrix grid frame, vertical shaft, wind power transmission, generator set landing, wind power distribution and power generation grouping mode.

The wind power generator includes: matrix grid frame, wind wheel vertical shaft group, cross axle transmission system, wind power distribution system, firm oblique support, wind power distribution system includes: the wind wheel vertical shaft group is arranged on the matrix-shaped grid frame, the transverse shaft transmission system is arranged under the matrix-shaped grid frame, the wind wheel vertical shaft group is connected with the transverse shaft transmission system, the wind wheel vertical shaft group transmits wind power to the transverse shaft transmission system, the matrix-shaped grid frame is supported by the stable inclined support, the transverse shaft transmission system is connected with the generator set, the generator set is provided with the automatic control system, the automatic control system determines to start the number of the generator set according to the wind quantity, the electric sloping cam plate is connected with the wind wheel vertical shaft group, and the electric sloping cam plate adjusts the wind blades in the wind wheel vertical shaft group according to the wind direction and the wind quantity. The matrix-shaped grid framework 1 is an assembly combination body, a buckling piece 12 is formed by a buckling plate 13 and a corner seat 14, and the buckling piece 12 connects and assembles the transverse pipe 10 and the vertical pipe 11. The wind wheel vertical shaft groups 2 are longitudinally densely arranged in the matrix-shaped grid frame 1 and are fixed on the transverse pipes 10 layer by layer. The transverse shaft transmission system 3 is arranged at the lower end of the wind wheel vertical shaft group 2, and wind power transmitted by the wind wheel vertical shaft group 2 is gathered on the transverse shaft transmission system 3. An electric putter machine 87 in the electric swash plate 6 controls a putter 88. The technical problems to be solved in the utility model are as follows: the wind direction of the wind power transmitted to the transverse-axis distribution type wind power generator by the vertical axis of the matrix frame is controlled on the fan blade. The maximum bearing surface of the fan blade always keeps vertical intersection to the windward direction, and the wind passing surface is parallel to the wind direction. When the wind wheel rotates, the blades are controlled by the electric swash plate 6, when the rotary plate 63 on the electric swash plate 6 is parallel, the blades are regulated to be parallel, when three push rods 88 in the electric push rod machine 87 move, the rotary plate 63 starts to incline, the blades gradually hang down to the maximum windward side or the controlled optimal angle with the wind direction during the inclination, and then the blades gradually cut into the direction parallel to the wind direction within one circle of rotation, and the whole process is that the blades gradually turn over and change within the range of 0-90 degrees every circle of rotation, so as to regulate the conversion of the windward side and the windward side.

Example 1:

as shown in figures 1, 2 and 3, the vertical shaft wind power of the matrix frame of the utility model is transmitted to the front view, the left view and the top view of the horizontal shaft distributed wind power generator, the structural characteristics of the wind power generator are completely expressed, and the matrix grid frame 1, the wind wheel vertical shaft group 2 and the horizontal shaft transmission system 3 in the front view 1 show the overall outline of the wind power generator. In the left view 2, the oblique bracket 5, the generator set 4 and the electric sloping cam plate 6 are firmly fixed, and in the figure, the position relation of structural members in the wind driven generator is shown. The generator set 4 in fig. 1, 2 and 3 is floor mounted in the generator room 7.1-7.3. The wind wheel vertical shaft group 2 transmits wind power to the transverse shaft transmission system 3, and the wind power is regulated and controlled according to the wind quantity and distributed to several or all of the generator sets 4 to generate power. The electric sloping cam plate 6 in fig. 2 adjusts the fan blade in the wind wheel vertical shaft group 2 to turn over according to the wind direction and the wind quantity, and changes in windward and windward cutting.

As shown in figure 4, the vertical shaft wind power of the matrix frame is transmitted to the horizontal shaft distribution type wind power generator, and the wind power generator is built in the peak top inclined direction. The wind driven generator is fixed in the inclined direction of the peak top, the wind driven generator is integrally fixed on a slope angle by using an inclined bracket 8, and the angle adjusting transmission box 9 is used for adjusting the wind wheel vertical shaft group and the wind in the inclined direction to be at the best position.

The wind power generator with the matrix frame vertical shaft wind power transmitted to the transverse shaft distribution type wind power generator is a matrix grid frame connecting method as shown in fig. 5, 6 and 7, wherein pipe fittings in the vertical and vertical intersection of the frame are assembled into a grid shape by using buckling pieces 12, wherein the cross joint of the transverse pipe 10 and the vertical pipe 11 is buckled and pressed by a buckling plate 13 through a corner seat 14 and then tightly pressed and fastened by using bolts 15, so as to form the matrix grid frame.

As shown in figure 8, the vertical shaft wind power of the matrix frame is downwards transmitted to the transmission system 3 of the horizontal shaft distribution type wind driven generator, and the long and long downlink horizontal shafts are not independent and are formed by connecting a plurality of short shafts and a plurality of transmission boxes. Two output shaft right angle transmission boxes 16 are arranged at two ends of the downlink transverse shaft transmission system 3, a three-output shaft parallel transmission box 17 is arranged in the middle of the downlink transverse shaft transmission system, and four output shaft right angle transmission boxes 18 are power output transmission boxes, wherein one end of each power output transmission box is output to a generator set. A short shaft 19 is connected between each transmission case, and the transmission cases are connected together to form the long and long descending transverse shaft transmission system 3. The wind power from each transmission box is converged into resultant force by the downlink cross shaft transmission system 3, and then the resultant force is respectively supplied to the output shafts of the four-output-shaft angle transmission boxes 18 to the generator sets (three four-output-shaft angle transmission boxes are arranged in fig. 3), the three generator sets are connected, and the automatic control system can automatically determine the number of the generator sets to be started according to the air quantity to form distributed power generation.

The matrix frame vertical shaft wind power transmission of the utility model shown in figure 9 is depicted as a wind wheel vertical shaft group, the wind wheel groups 22.1-22.3 are connected into a whole, and the shaft bases 20.1-20.3 and the vertical shaft 21 are fixed on the frame to form an independent unit to form a basic module.

The vertical shaft wind power down-transmission of the matrix frame of the utility model shown in fig. 10 and 11 is depicted as a group of wind wheels in a horizontal shaft distribution type wind driven generator, namely, the wind wheels 23.1-23.5 are correspondingly arranged in one grid in the matrix grid frame, each wind wheel is provided with three blades 24.1-24.3, and the wind wheels rotate within the range of 0-90 degrees according to the requirement of the wind receiving surface during rotation.

The vertical shaft wind power down-transmission of the matrix frame of the utility model shown in fig. 12 and 13 is in a cross shaft distribution type wind driven generator, a fan blade structure is described, a fan blade shaft 28 is elliptical at a fan blade mounting position, a fan blade 25 and a fan blade 26 are symmetrically buckled on the fan blade shaft 28, and the fan blade 25 and the fan blade 26 are riveted together through rivets 27.

The wind power transmission of the matrix frame vertical shaft of the utility model shown in fig. 14 is depicted in the structural relationship between the fan blades and the shaft in the transverse shaft distribution type wind driven generator, the root of the fan blade shaft 28 is gradually rounded from ellipse, a short shaft 29 is assembled in a pressing mode at a shaft nest 30 to be firmly integrated, the other end of the short shaft 29 is assembled with a coupler 31, and a shaft penetrating shaft 36 is used for fixing the two parts. The coupling 32 is screwed to the toothed shaft 33, likewise secured by a shaft. The coupling 31 and the coupling 32 are fastened together with bolts 35. The tooth part at the shaft end 34 of the tooth shaft 33 is used for driving the fan blade to turn over to change between the windward angle and the wind direction tangent line, and the change is carried out once per rotation.

The vertical shaft wind power down-transmission of the matrix frame of the utility model shown in fig. 15 and 16 is in a horizontal shaft distribution type wind driven generator, and the relation of a wind wheel group shaft is described, an upper shaft seat 37 and a lower shaft seat 39 are used for fixing a wind wheel group in the matrix grid frame, the upper wind wheel group and the lower wind wheel group are communicated, the wind wheel seats 38.1-38.5 are equidistantly separated by a rotating sleeve 41.1-41.4, and a short shaft sleeve 51 is a space adjusting sleeve. The vertical shafts 21 occupy half of the upper shaft seat 37, two flat keys 52 are connected into a concentric shaft, and the lower shaft seat 39 is connected in the same way as the upper shaft seat 37. The upper shaft seat 37 and the lower shaft seat 39 are composed of a plurality of parts, an outer solid 43 is connected with the frame, a thrust bearing 45 and a ball bearing 48 are arranged in a shaft seat body 42 for positioning and rotating by a shaft sleeve 44, and an upper end cover 46/49 and a lower end cover 46/49 are respectively assembled and fastened by bolts 47/50.

The effect of the wind wheel set shaft in the wind wheel base 38.1-38.5 is described in the matrix frame vertical shaft wind power transmission of the utility model shown in fig. 15, 17 and 18 in the horizontal shaft distributed wind power generator, when the wind power rotates the wind wheel base 38.1-38.5, the vertical shaft 21 fixed at the center rotates to transmit the wind power, the push-pull shaft 40.1-40.3 also rotates coaxially at the same speed, and simultaneously, the angle of the regulating blade is moved up and down, and the tooth part at the shaft end 34 of the tooth shaft 33.1-33.3 rotates when the push-pull shaft 40.1-40.3 moves up and down. The gear shafts 33.1-33.3 are respectively arranged in the wind wheel base 38, in the needle bearing 53, the ball bearing 54 and the thrust bearing 55, and the end cover 56 is pressed by the bolts 57.

In the matrix frame vertical shaft wind power downloading of the utility model shown in fig. 15 and 19, the push-pull shafts 40.1-40.3 are connected in the upper shaft seat 37 and the lower shaft seat 39 by a handshake groove, so that the push-pull shafts 40.1-40.3 move up and down and rotate synchronously.

The electric sloping cam plate 6 in figure 2 is described in the vertical shaft wind power transmission of the matrix frame of the utility model in figures 20, 21, 22 and 23 in the horizontal shaft distribution type wind driven generator, and the device is used for adjusting the matching relation between the fan blades and the wind intensity and the wind direction. The electric swash plate 6 is composed of two parts, one is a non-rotating part and the other is a rotating part, and the two parts are on the axis of a rotating vertical shaft. The non-rotating portion starts from the lower bottom cover 80, four electric putter machines 87 are respectively fixed to the bottom cover 80, and the electric putter motor 87 swings when it is lifted, so that the upper end of the electric putter machine 87 is fixed to one ball 84 by a bolt 85, the upper ball cover 81 and the lower ball cover 83 of the ball 84 are fixed in the middle by a bolt 82 and are movable, and the motor cover 86 is connected to the ball 84 by a bolt 85. The cage 74, which is centered on the axis, is also secured to the bottom cover 80 by bolts 75, which function to secure the non-rotating member. The swinging sleeve 73 at the center of the ball cage 74 is used for stabilizing the control disc 72, and the lifting push rod 88 is firmly locked in the long groove of the control disc 72. The electric push rod motor 87 enables the lifting push rod 88 to move up and down to be connected with the hinge shaft 71, so that the posture of the tray 70 is changed without rotating. The non-rotating tray 70 is separated from the turntable 63 by a thrust bearing 69 and a ball bearing 68, and a gland 77 is fixed by bolts 78. The rotating part is that a rotating disc 63 and a lower arc sleeve 76 clamp a rotating ball 66 in the middle and are assembled by bolts 64, and the rotating ball 66 is fixed on a shaft by flat keys 65 and jackscrews 67. The hinge shaft 71 pushes the non-rotating tray 70 to displace parallel to the turntable 63, the hinge shaft 62 on the turntable 63 is connected to one end of the link 61, and the other hinge shaft 60 is connected to the push-pull shafts 40.1 to 40.3. The length of the push rod 88 is determined by the electric push rod motor 87, so that the same change of the posture of the tray 70 and the turntable 63 is realized without rotating, the push-pull shafts 40.1-40.3 move up and down, and the changing track of the push-pull shafts influences the change angle of the wind blades 24.1-24.3. The whole electric swash plate 6 is fixed on the lower shaft seat 39, the upper cover plate 58 is fixed on the lower shaft seat 39 by bolts 79, the upper cover plate 58 is fixed on the outer cylinder 59 by bolts 92, and the lower bottom cover 80 is fixed on the outer cylinder 59 by bolts 93. The lower end of the ball cage 74 is centered with the vertical shaft 21 by a ball bearing 91, and a bearing cover 94 is pressed by a bolt 90. 95 is the output shaft, 89 is the shaft coupling.

Claims (5)

1. A matrix frame vertical axis wind down-transferred to horizontal axis distributed wind turbine, the wind turbine comprising: matrix grid frame (1), wind wheel vertical shaft group (2), cross axle transmission system (3), wind power distribution system, firm oblique support (5), wind power distribution system includes: the wind turbine generator comprises a generator set (4), an automatic control system and an electric swash plate (6), wherein the wind turbine vertical shaft group (2) is arranged on the matrix-shaped grid frame (1), the transverse shaft transmission system (3) is arranged on the matrix-shaped grid frame (1), the wind turbine vertical shaft group (2) is connected with the transverse shaft transmission system (3), the wind turbine vertical shaft group (2) transmits wind power to the transverse shaft transmission system (3), the firm inclined support (5) supports the matrix-shaped grid frame (1), the transverse shaft transmission system (3) is connected with the generator set (4), the generator set (4) is provided with the automatic control system, the automatic control system determines the number of the generator sets to be started according to wind quantity, the electric swash plate (6) is connected with the wind turbine vertical shaft group (2), and the electric swash plate (6) adjusts wind quantity in the wind turbine vertical shaft group (2) according to wind direction.

2. A matrix frame vertical shaft wind power down-transmission horizontal shaft distribution type wind power generator according to claim 1, wherein the matrix grid frame (1) is an assembled assembly, a buckling piece (12) is formed by a buckling plate (13) and a corner seat (14), and the buckling piece (12) is used for connecting and assembling a horizontal pipe (10) and a vertical pipe (11).

3. A matrix frame vertical shaft wind power down-transmission horizontal shaft distribution type wind power generator according to claim 1 or 2, characterized in that the wind wheel vertical shaft group (2) is longitudinally densely arranged in the matrix grid frame (1) and is fixed on the horizontal pipe (10) layer by layer.

4. The matrix frame vertical shaft wind power downward-transmission type cross shaft distribution type wind driven generator according to claim 1, wherein the cross shaft transmission system (3) is arranged at the lower end of the wind wheel vertical shaft group (2), and the wind wheel vertical shaft group (2) downward-transmission wind power is gathered on the cross shaft transmission system (3).

5. A matrix frame vertical shaft wind down-wind generator according to claim 1, characterised in that the electric putter machine (87) in the electric swash plate (6) controls the putter (88).

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