WO2012174864A1

WO2012174864A1 - Eccentric ring wind power mechanism

Info

Publication number: WO2012174864A1
Application number: PCT/CN2012/070558
Authority: WO
Inventors: 刘海平
Original assignee: Liu Haiping
Priority date: 2011-06-20
Filing date: 2012-01-19
Publication date: 2012-12-27
Also published as: CN202176453U

Abstract

An eccentric ring wind power mechanism comprising several wind board assemblies (13), a connection driving assembly (14), and a movable round ring (16) capable of moving in the horizontal direction. The end portion of the inner side of the wind board assembly moves inside of a guiding slot (17) on the movable round ring (16) when subjected to wind. The wind board assemblies (13) are rotatably mounted at the periphery of the connection driving assembly (14), are in fixed positions relative to the connection driving assembly (14), and drive the connection driving assembly (14) to rotate. At the same time, the inner boards of the wind board assemblies (13) apply pressures to the movable round ring (16). The resultant force of the pressures applied by the wind board assemblies (13) to the movable round ring (16) determines the position of the movable round ring (16), so that the wind board assemblies are always kept at the most reasonable position when subjected to wind, thereby improving wind energy utilization efficiency.

Description

Eccentric ring wind mechanism

Technical field

This invention relates to wind power installations and, more particularly, to an eccentric ring wind mechanism.

Background technique

Today, with petrochemical and coal-fired energy sources fading, wind power or output power has become one of the key directions for human energy development. The data show that the total amount of wind energy resources that can be developed globally is about many times the total amount of human energy demand. The richness of wind energy and natural regenerability are the most attractive reasons.

Wind power technology originated in Europe, and Denmark, the Netherlands, Germany and other countries have been developing and advocating wind power for more than 20 years. Since the birth of wind power technology, it has undergone continuous improvement. At present, the more commonly used wind turbines can be divided into two categories:

1) Horizontal axis wind turbine whose vertical axis of the wind wheel is parallel to the direction of the air flow. The horizontal axis wind turbine is mainly composed of a tower, a horizontal shaft wind wheel, a gearbox (acceleration gear box), a generator, a wind device, a control system and the like. The role of the wind wheel is to convert wind energy into mechanical energy. It is composed of a vane with good gas flow performance on the axle. The low-speed rotating wind turbine accelerates the gearbox through the transmission mechanism, and then transmits the power to the generator. The main advantage of the horizontal axis wind turbine is that the wind wheel can be erected to a higher position from the ground, which reduces the influence of the ground disturbance on the dynamic characteristics of the wind wheel. The higher the wind turbine is set off the ground, the greater the wind force and the higher the power generation with the height. Increased, the starting wind speed is low, and it can be started automatically. The disadvantage is that the blade design and the wind wheel manufacturing are more complicated; and an additional wind device is needed to adjust the wind direction of the blades of the wind wheel, which increases the design difficulty and cost.

2) Vertical axis wind turbine whose vertical axis of the wind wheel is perpendicular to the ground or airflow direction. Usually, the vertical axis wind turbine is installed close to the ground, without using the tower and the wind device; the vertical axis wind turbine receives the wind, drives the vertical shaft to rotate, and drives the generator to rotate through the gearbox. The advantage is that no wind is needed when the direction of the air flow changes, and no wind device is needed, and the gyro force when the wind wheel is against the wind is reduced. The structure is relatively simple and the cost is low. However, the wind energy utilization rate of the vertical axis wind turbine is lower than that of the horizontal axis. The wind turbine is close to the ground and the airflow is greatly affected by the ground. Moreover, since the wind plates of the vertical axis wind turbine are usually fixed, the wind power cannot be more fully accepted. The conversion efficiency is low and cannot meet the actual demand.

Summary of the invention

The technical problem to be solved by the present invention is to provide an eccentric ring wind mechanism with high wind energy utilization efficiency and simple structure.

The technical solution adopted by the present invention to solve the technical problem thereof is to provide an eccentric ring wind mechanism, comprising a plurality of wind plate assemblies, and a connecting drive assembly driven by the wind plate assembly; the eccentric ring wind The mechanism also includes a movable ring positioned by the wind panel assembly and having a guide slot;

The inner end of the wind plate assembly moves in a guiding groove of the movable ring when receiving wind; the resultant force formed by the wind plate assembly when the wind is received by the wind pushes the movable ring to translate and rotate in a horizontal direction;

The wind panel assembly is swingably mounted on a periphery of the connection drive assembly and drives the connection drive assembly to rotate, and the position of the connection drive assembly is relatively fixed.

In the eccentric ring wind mechanism of the present invention, the wind panel assembly is divided into an inner panel and an outer panel by a position connecting the connecting driving components, and an area of the outer panel is larger than an area of the inner panel;

An end of the inner panel of the air panel assembly is provided with an inner panel roller, and the inner panel roller is rotatably coupled to the guide slot.

In the eccentric ring wind mechanism of the present invention, the eccentric ring wind mechanism further includes a vertically disposed vertical axis;

The connection driving assembly includes two groups respectively disposed at upper and lower ends of the vertical axis; the axis of the connection driving assembly is coaxial with the vertical axis;

The inner panel is a side of the wind panel assembly adjacent to the vertical axis, and the outer panel is a side away from the vertical axis.

In the eccentric ring wind mechanism of the present invention, the connection drive assembly includes a plurality of drive links respectively disposed at upper and lower ends of the vertical axis; each of the drive links corresponds to one of the wind plate assemblies, An inner end of the driving link is connected to the vertical shaft, and an outer end of the driving link is provided with a connecting hole;

The upper and lower sides of the wind plate assembly are provided with wind plate rollers, and the wind plate rollers on the two sides are respectively rotatably inserted into the connecting holes of the corresponding driving links.

In the eccentric ring wind mechanism of the present invention, the inner end of the drive link is coupled to the vertical shaft by a bearing; and a plurality of magnets or induction coils are disposed on the drive link.

In the eccentric ring wind mechanism of the present invention, the eccentric ring wind mechanism further includes a rotatable inner fixed ring located inside the movable ring; the inner fixed ring is concentrically arranged with the vertical axis, and Located at the same horizontal position as the active ring.

In the eccentric ring wind mechanism of the present invention, the inner fixed ring is fixedly coupled to the drive link and rotates about the vertical axis; the inner fixed ring is provided with a plurality of magnets or induction coils.

In the eccentric ring wind mechanism of the present invention, the width of the wind plate roller to the inner plate roller plus the radius of the inner fixed ring is greater than the vertical axis to the wind plate roller length.

In the eccentric ring wind mechanism of the present invention, the outer end of the drive link is provided with an outer fixed ring concentric with the vertical axis; the connecting hole is disposed on the drive link or the outer fixed On the ring.

In the eccentric ring wind mechanism of the present invention, the outer fixed ring is fixedly coupled to the drive link and rotates about the vertical axis; the outer fixed ring is provided with a plurality of magnets or induction coils.

In the eccentric ring wind mechanism of the present invention, the width of the wind plate roller to the inner plate roller plus the length of the movable ring diameter is larger than the diameter of the outer fixed ring; or

The width of the wind plate roller to the inner plate roller plus the length of the movable ring diameter is equal to the diameter of the outer fixed ring;

And the guiding groove of the movable ring must be provided with a plurality of partitions, the partitions being of the same size and equal in number to the number of the wind plates.

In the eccentric ring wind mechanism of the present invention, the arcuate total length of the wind panel assembly is greater than or equal to the circumference of the outer fixed ring, and the inner plate roller is detachable from the movable ring The guiding grooves are connected end to end to form a cylinder.

In the eccentric ring wind mechanism of the present invention, the wind plate assembly includes a resistance type wind plate or a lift type wind plate; the wind plate is a solar battery wind plate.

In the eccentric ring wind mechanism of the present invention, the eccentric ring wind mechanism further includes a slewing body fixedly mounted on a lower side of the connecting drive assembly, and a water absorbing member is mounted on a lower side of the outer surface of the whirlpool.

The present invention also provides an eccentric ring wind mechanism comprising a plurality of wind plate assemblies, and a connection drive assembly driven by the wind plate assembly to output power;

The wind panel assembly is rotatably mounted on a periphery of the connecting drive assembly, and the wind panel assembly is divided into an inner panel and an outer panel by a position connecting the connecting driving components, the outer panel having an area larger than The area of the inner panel;

The eccentric ring wind mechanism further includes a movable ring that can be translated in a horizontal direction; the movable ring is provided with a guiding groove; and an end of the inner plate of the wind plate assembly is provided with an inner plate roller, The inner plate roller is rotatably coupled to the guide groove;

The wind panel assembly drives the connection drive assembly to rotate, and the position of the connection drive assembly is relatively fixed.

The connecting drive assembly includes two groups respectively disposed at upper and lower ends of the vertical shaft; the axis of the connecting driving assembly is fixedly connected with the vertical shaft to drive the vertical shaft to rotate;

In the eccentric ring wind mechanism of the present invention, the connection drive assembly includes a plurality of drive links respectively disposed at upper and lower ends of the vertical axis;

Each of the driving links corresponds to one of the wind plate assemblies, an inner end of the driving link is fixedly connected to the vertical shaft, and an outer end of the driving link is provided with a connecting hole;

In the eccentric ring wind mechanism of the present invention, the eccentric ring vertical wind turbine further includes an inner fixed ring located inside the movable ring; the inner fixed ring is rotatable relative to the drive link, and Relatively fixed position;

The inner fixed ring is concentrically disposed with the vertical axis and is at the same horizontal position as the movable ring.

In the eccentric ring wind mechanism of the present invention, the width of the inner panel plus the radius of the inner fixed ring is greater than the length of the vertical axis to the wind plate roller.

In the eccentric ring wind mechanism of the present invention, the outer end of the drive link is fixedly provided with an outer fixed ring; the connecting hole is disposed on the outer fixed ring.

In the eccentric ring wind mechanism of the present invention, the width of the inner panel plus the length of the movable ring diameter is larger than the diameter of the outer fixed ring; or

The width of the inner panel plus the length of the movable annular ring is equal to the diameter of the outer fixed ring, the partition is provided with a plurality of partitions, and the partitions have the same size, the number is equal to the wind plate quantity.

In the eccentric ring wind mechanism of the present invention, the wind plate assembly includes a resistance type wind plate or a lift type wind plate; the wind plate is a solar battery wind plate; the inner plate roller and/or the wind plate roller There are bearings on the periphery.

The invention has the following beneficial effects: when the wind panel assembly is subjected to wind, the driving connection driving assembly rotates, and the inner panel of the wind panel assembly gives a pressure to the movable ring, and the greater the opening of the wind panel assembly gives the pressure of the movable ring. The larger the combined force of the wind plate assembly to the active ring pressure determines the position of the movable ring, so that the wind plate assembly is always maintained at the most reasonable position of the wind, thereby improving the utilization efficiency of the wind energy; and, without the prior art level The various wind-driven devices of the axial wind turbine have a simple and reasonable structure.

DRAWINGS

The present invention will be further described below in conjunction with the accompanying drawings and embodiments, in which:

1 is a top plan view of a first embodiment of an eccentric ring wind mechanism of the present invention;

Figure 2 is a partial cross-sectional view showing the first embodiment of the eccentric ring wind mechanism of the present invention;

Figure 3 is a partial enlarged view of the portion A of Figure 2;

4 is a top plan view showing a first embodiment of the eccentric ring wind mechanism of the present invention using a lift type wind receiving member;

Figure 5 is a top plan view showing a second embodiment of the eccentric ring wind mechanism of the present invention;

Figure 6 is a top plan view showing a third embodiment of the eccentric ring wind mechanism of the present invention;

Figure 7 is a partial cross-sectional view showing a fourth embodiment of the eccentric ring wind mechanism of the present invention;

Figure 8 is a partial cross-sectional view showing a fifth embodiment of the eccentric ring wind mechanism of the present invention;

Figure 9 is a partial cross-sectional view showing a sixth embodiment of the eccentric ring wind mechanism of the present invention.

detailed description

As shown in FIG. 1 to FIG. 4, it is a first embodiment of the eccentric ring wind mechanism of the present invention, which is used as a wind turbine, and includes a vertically disposed vertical shaft 11 and two sets of connections respectively disposed at upper and lower ends of the vertical shaft 11. Drive assembly, and several wind panel components.

The vertical shaft 11 is disposed in the vertical direction and is driven to rotate by the connection drive assembly. The output of the vertical shaft 11 can drive a generator or other power machine to convert wind energy into a kinetic energy output. The windshield assembly is used as the wind receiving member 13 to be rotated by the wind-driven connection driving assembly, and includes a wind plate roller 12 disposed in parallel with the vertical shaft 11, and a wind receiving member 13 fixedly coupled to the wind plate roller 12. The wind panel assembly can employ various wind panel assemblies of the prior art, such as the windsurfing assembly disclosed in Chinese Patent No. 200920133508.3. The wind receiving member 13 of the air panel assembly may be a resistance type wind plate or a lift type air plate (as shown in FIG. 4). Of course, the wind receiving member 13 of the wind panel assembly can also be fabricated using a solar panel so that power can be generated in combination with solar energy.

In this embodiment, the connection driving assembly is connected as a power transmission component between the vertical shaft 11 and the wind plate assembly, and may include two groups disposed at the upper and lower ends of the vertical shaft 11 separately. . The shaft of the connecting drive assembly is fixedly coupled to the vertical shaft 11 and the outer end is coupled to the wind panel assembly.

In this embodiment, the connection drive assembly includes a plurality of vertical axes respectively disposed 11 drive links 14 at the upper and lower ends. The number of drive links 14 corresponds to the wind plate assembly, the inner end of the drive link 14 is fixedly coupled to the vertical shaft 11, and the outer end is coupled to the wind plate assembly. A connecting hole 15 is disposed at an outer end of the driving link 14, and the upper and lower wind plate rollers 12 of the wind plate assembly are rotatably inserted into the connecting holes 15 of the corresponding upper and lower driving links 14 Thus, the air panel assembly can push the drive link 14 to rotate, and the wind plate assembly can also be rotated about the wind plate roller 12. Of course, the drive link 14 can also take other forms, such as a connecting disc, a hollow disc, and the like.

It can be understood that bearings or the like can be mounted on the periphery of the wind plate rollers 12 to reduce the friction between the wind plate roller 12 and the connecting hole 15 of the drive link 14.

In order to keep the wind plate assembly in a reasonable wind position during rotation, the eccentric ring wind mechanism is also provided with a movable ring 16 that can be translated in the horizontal direction. In this embodiment, the movable ring 16 is respectively disposed on the upper and lower sides of the wind plate assembly, and of course, only one of them may be provided as needed.

Each of the movable rings 16 is provided with a guide groove 17; correspondingly, an end plate roller 18 is provided at an end of the inner plate of the wind plate assembly, and the inner plate roller 18 is rotatably inserted into the guide groove 17. It will be appreciated that the periphery of the inner plate roller 18 may also be provided with bearings to reduce friction between the inner plate roller 18 and the guide groove 17.

In the present embodiment, the wind plate assembly is divided into an inner plate on the side close to the vertical axis 11 and a position away from the vertical axis 11 at a position where the drive assembly is connected, that is, a line connecting the wind plate rollers 12 on the upper and lower sides. The outer panel of one side; and the area of the outer panel is larger than the area of the inner panel, so that the wind receiving area of the outer panel is always larger than the wind receiving area of the inner panel, forming the pushing movable ring 16 to reach a proper position, and pushing the connecting driving component The resultant force of rotation.

When the wind panel assembly is subjected to the wind, each wind panel assembly applies a pressure to the movable ring 16. The greater the opening of the wind plate, the greater the pressure on the movable ring 16, and the resultant force of the wind plate assembly to the movable ring 16 determines. The position of the active ring 16. When the wind plate assembly is rotated about the vertical axis 11, since the inner plate roller 18 is inserted into the guide groove 17, it is guided by the guide groove 17, thereby changing the wind receiving angle of the wind plate assembly, so that the wind plate assembly is always kept in the wind. The most reasonable location improves the efficiency of wind energy utilization.

Further, in order to limit the movable ring 16, support the drive link 14, and the like, an inner fixed ring 19 fixedly connected to the drive link 14 is further disposed inside the movable ring 16. The inner fixed ring 19 is concentric with the vertical axis 11 and is in the same horizontal position as the movable ring 16. The width of the inner panel of the wind panel assembly plus the radius of the fixed ring is greater than the length of the vertical shaft 11 to the wind plate roller 12, thereby ensuring that the movable ring 16 does not exceed the limit position, and avoids the wind plate of the wind plate assembly. Being blown over.

In order to reduce the friction between the movable ring 16 and the inner fixed ring 19, the inner fixed ring 19 bearing may be fixedly mounted on the outer circumference of the inner fixed ring 19. Alternatively, the inner fixed ring 19 is provided to include a separate inner ring and an outer ring, and a rolling member such as a ball or a roller is disposed between the inner ring and the outer ring.

As shown in FIG. 5, it is a second embodiment of the eccentric ring wind mechanism of the present invention, which differs from the first embodiment in that an outer fixed ring 20 fixedly disposed at the outer end of the drive link 14 is used instead of The ring 19 is fixed, and the connecting hole 15 is provided on the outer fixing ring 20, so that the wind plate assembly is rotatably inserted and mounted on the outer fixing ring 20. Moreover, the outer fixed ring 20 and the movable ring 16 are in the same horizontal position, so that the movable ring 16 can only move horizontally within the outer fixed ring 20, and functions as a limit movable ring 16.

In order to prevent the wind plate assembly from being blown over, the width of the inner plate plus the diameter of the movable ring 16 is greater than the diameter of the outer fixed ring 20. Alternatively, the width of the inner panel plus the length of the diameter of the movable ring 16 is equal to the diameter of the outer fixed ring 20. At this time, a plurality of partitions are provided in the movable ring 16, and the sizes of the partitions are the same, and the number is equal to the number of the wind plates.

Further, the total length of the arc surface of the design wind plate assembly is greater than or equal to the circumference of the outer fixed ring 20, so that when the wind plate assembly is not rotated, it can be fixedly arranged between the upper and lower outer fixed rings 20, The inner plate roller 18 can be separated from the guiding groove 1 of the movable ring 16 and connected end to end to form a cylinder, so that when the wind speed is too large, the wind turbine is prevented from being damaged.

It can be understood that, in combination with the first embodiment and the second embodiment described above as the third embodiment, the inner fixing ring 19 and the outer fixing ring 20 can be simultaneously disposed, as shown in FIG.

In the fourth example of the eccentric ring wind mechanism of the present invention, the difference from the above embodiment is that the floating body 21 is fixedly mounted on the lower side of the connecting drive unit, as shown in FIG. The cyclone 21 can be formed as a hollow torus to provide sufficient buoyancy to support the entire wind turbine so that the entire mechanism can be used on the water. The connection between the cyclone and the connection drive assembly can be referred to the Chinese invention patent ZL200920134710.8. Of course, other connection methods can also be used without limitation.

In the fifth example of the eccentric ring wind mechanism of the present invention, the mechanism can be used as a wind water water machine, which differs from the above embodiment in that a floating body 21 is fixedly mounted on the lower side of the connecting drive assembly, and is in a spiral The water-removing member 22 is fixedly mounted on the outer lower side of the member 21, as shown in FIG. For the connection structure of the water-repellent member 22 and the cyclone body 21, reference may be made to the Chinese patent ZL200920134813.4. Of course, other connection manners may be adopted as long as the rotation of the driving assembly is driven by the wind plate assembly, thereby driving the rotary body 21 to rotate. , the water-repellent member 22 can be driven to dial water.

As shown in FIG. 9, a sixth example of the eccentric ring wind mechanism of the present invention is different from the above embodiment in that the connecting drive assembly and the vertical shaft 11 are connected by a bearing 23, that is, the vertical shaft 11 is fixedly disposed. As a mounting support, the connecting drive assembly is concentric with the vertical shaft 11 and is rotatable about the vertical axis 11. In the present embodiment, a bearing is disposed between the link 14 connecting the drive assembly and the vertical shaft 11, so that the link 14 can be rotated about the vertical axis 11 by the wind plate assembly. It can be understood that the inner fixed ring and/or the outer fixed ring can also rotate about the vertical axis 11 when the inner fixed ring and/or the outer fixed ring are provided.

Further, on the connecting driving component (such as the connecting rod 14, the inner fixing ring and/or the outer fixing ring), a plurality of magnets 24 or induction coils connected with the driving assembly may be disposed; correspondingly, A plurality of induction coils 25 or magnets are disposed at corresponding positions of the connection drive components. Of course, the induction coils 25 or magnets can be fixedly mounted by various existing methods as needed. The induction coils 25 are vertically disposed and arranged side by side at positions corresponding to the magnets 24. When the connecting drive assembly is driven by the wind plate assembly to rotate about the vertical axis 11, the magnet 24 moves in a circular motion under the driving of the driving assembly. When passing through the position of the induction coil 25, the induction coil 25 is induced by the electromagnetic induction principle. Current converts wind energy into electrical energy for electrical energy output.

It is to be understood that those skilled in the art will be able to make modifications and changes in accordance with the above description, and all such modifications and variations are intended to be included within the scope of the appended claims.

Claims

An eccentric ring wind mechanism, comprising: a plurality of wind plate assemblies, a connecting drive assembly driven by the wind plate assembly to output power, and a movable ring positioned by the wind plate assembly and having a guiding groove;

The inner end of the wind panel assembly moves within the guiding groove of the movable ring when subjected to wind, and the resultant force formed when the wind plate assembly receives wind pushes the movable ring to translate and rotate in the horizontal direction ;

The wind panel assembly is swingably mounted on a periphery of the connection drive assembly, relatively fixed to a position of the connection drive assembly, and drives the connection drive assembly to rotate.
The eccentric ring wind mechanism according to claim 1, wherein the wind plate assembly is divided into an inner panel and an outer panel by a position connecting the connection driving components, and an area of the outer panel is larger than The area of the inner panel;

An end of the inner panel of the air panel assembly is provided with an inner panel roller, and the inner panel roller is rotatably coupled to the guide slot.
The eccentric ring wind mechanism according to claim 2, wherein the eccentric ring wind mechanism further comprises a vertically disposed vertical axis;

The connection driving assembly includes two groups respectively disposed at upper and lower ends of the vertical axis; the axis of the connection driving assembly is coaxial with the vertical axis;

The inner panel is a side of the wind panel assembly adjacent to the vertical axis, and the outer panel is a side away from the vertical axis.
The eccentric ring wind mechanism according to claim 3, wherein said connecting drive assembly comprises a plurality of driving links respectively disposed at upper and lower ends of said vertical shaft; each of said driving links and said wind Corresponding to the plate assembly, the inner end of the driving link is connected to the vertical axis, and the outer end of the driving link is provided with a connecting hole;

The upper and lower sides of the wind plate assembly are provided with wind plate rollers, and the wind plate rollers on the two sides are respectively rotatably inserted into the connecting holes of the corresponding driving links.
The eccentric ring wind mechanism according to claim 4, wherein an inner end of the drive link is coupled to the vertical shaft via a bearing; and a plurality of magnets or induction coils are disposed on the drive link .
The eccentric ring wind mechanism according to claim 3, wherein the eccentric ring wind mechanism further comprises a rotatable inner fixed ring located inside the movable ring; the inner fixed ring and the inner ring The vertical axis is concentrically disposed and in the same horizontal position as the active ring.
The eccentric ring wind mechanism according to claim 6, wherein the inner fixed ring is fixedly coupled to the drive link and rotates about the vertical axis; the inner fixed ring is provided with a plurality of Magnet or induction coil.
The eccentric ring wind mechanism according to any one of claims 4 to 7, wherein the width of the wind plate roller to the inner plate roller plus the radius of the inner fixed ring is greater than The length of the vertical axis to the wind plate roller.
The eccentric ring wind mechanism according to any one of claims 4 to 7, wherein an outer end of the drive link is provided with an outer fixed ring concentric with the vertical axis; the connecting hole is disposed at The drive link or the outer fixed ring.
The eccentric ring wind mechanism according to claim 9, wherein the outer fixing ring is fixedly connected to the driving link and rotates around the vertical axis; the outer fixing ring is provided with a plurality of Magnet or induction coil.
The eccentric ring wind mechanism according to claim 9, wherein a width of the wind plate roller to the inner plate roller plus a length of the movable ring diameter is larger than that of the outer fixed ring Diameter; or,

The width of the wind plate roller to the inner plate roller plus the length of the movable ring diameter is equal to the diameter of the outer fixed ring;

And the guiding groove of the movable ring must be provided with a plurality of partitions, the partitions being of the same size and equal in number to the number of the wind plates.
The eccentric ring wind mechanism according to claim 2, wherein the total length of the arc surface of the wind panel assembly is greater than or equal to the circumference of the outer fixed ring, and the inner plate roller is detachable The guiding grooves of the movable ring are connected end to end to form a cylinder.
According to claim 2 An eccentric ring wind mechanism, characterized in that the wind plate assembly comprises a resistance type wind plate or a lift type wind plate; the wind plate is a solar battery wind plate;

The eccentric ring wind mechanism further includes a slewing body fixedly mounted on a lower side of the connecting drive assembly, and a water absorbing member is mounted on a lower side of the outer surface of the whirlpool.
According to claim 1 The eccentric ring wind mechanism is characterized in that the connecting drive assembly is provided with a plurality of magnets or induction coils rotating therewith.
An eccentric ring wind mechanism comprising a plurality of wind plate assemblies and a connection drive assembly driven by the wind plate assembly to output power;

The air panel assembly is rotatably mounted on a periphery of the connection drive assembly, and the wind panel assembly is divided into an inner panel and an outer panel by a position connecting the connection drive assembly, the outer panel The area is larger than the area of the inner panel;

The eccentric ring wind mechanism further includes a movable ring that can be translated in a horizontal direction; the movable ring is provided with a guiding groove; and an end of the inner plate of the wind plate assembly is provided with an inner plate roller, The inner plate roller is rotatably coupled to the guide groove;

The wind panel assembly drives the connection drive assembly to rotate, and the position of the connection drive assembly is relatively fixed.
The eccentric ring wind mechanism according to claim 15, wherein the eccentric ring wind mechanism further comprises a vertically disposed vertical axis;

The connecting drive assembly includes two groups respectively disposed at upper and lower ends of the vertical shaft; the axis of the connecting driving assembly is fixedly connected with the vertical shaft to drive the vertical shaft to rotate; or the connecting driving assembly The axis of the shaft is coaxial with the vertical axis, and the vertical axis is fixedly disposed, and the driving assembly rotates about the vertical axis;

The inner panel is a side of the wind panel assembly adjacent to the vertical axis, and the outer panel is a side away from the vertical axis.
The eccentric ring wind mechanism according to claim 15, wherein the connecting drive assembly comprises a plurality of driving links respectively disposed at upper and lower ends of the vertical shaft;

Each of the driving links corresponds to one of the wind plate assemblies, and an inner end of the driving link is fixedly connected to the vertical shaft or rotatably connected to the vertical shaft through a bearing, and the driving link is externally a connecting hole is arranged at the end;

The upper and lower sides of the wind plate assembly are provided with wind plate rollers, and the wind plate rollers on the two sides are respectively rotatably inserted into the connecting holes of the corresponding driving links.
The eccentric ring wind mechanism according to claim 17, wherein said eccentric annular vertical wind mechanism further comprises an inner fixed ring located inside said movable ring; said inner fixed ring being opposite said The drive link rotates while the position is relatively fixed;

The inner fixed ring is concentrically disposed with the vertical axis and is at the same horizontal position as the movable ring.
The eccentric ring wind mechanism according to claim 18, wherein the outer end of the driving link is fixedly provided with an outer fixing ring; the connecting hole is disposed on the driving link or the outer fixing ring ;
The eccentric ring wind mechanism according to claim 19, wherein the driving link, the inner fixing ring and the outer fixing ring are rotatably connected to the vertical shaft, the moving link and the inner fixing The ring and/or the outer fixed ring are provided with a number of magnets or induction coils.