阅读说明：本技术 一种利用旋转力增大受风量的风力发电设备 (Wind power generation equipment for increasing air receiving amount by utilizing rotating force ) 是由 余金斌 于 2019-11-05 设计创作，主要内容包括：本发明涉及风力发电技术领域,且公开了一种利用旋转力增大受风量的风力发电设备,包括立杆,所述立杆的表面活动连接有转轴,转轴的表面套接有轴套,轴套的表面固定连接有叶片,叶片的内部固定连接有连杆,所述连杆的表面活动连接有齿轮,齿轮的表面啮合有转动体,转动体的内部活动连接有偏向轮,转动体的表面固定连接有减震板。推动风向板向两边扩展开,如图5所示,当叶片转动至不受风面时,转动体与风向板的位置不变,此时风向板失去风吹动的力,开始释放之前被吹进气的力,即产生一个推动叶片旋转的力,释放过程中,风向板失去充气杆的支撑力开始收缩,如图7所示,从而达到了增大驱动叶片旋转力的效果。(The invention relates to the technical field of wind power generation, and discloses wind power generation equipment for increasing the air receiving quantity by utilizing a rotating force. Promote the wind vane to both sides expansion and open, as shown in fig. 5, when the blade rotated to not receiving the wind-force, the position of rotor and wind vane was unchangeable, and the wind vane loses the power that wind blown this moment, and the power of being blown before beginning the release produces the rotatory power of a promotion blade promptly, and in the release process, the wind vane loses the holding power of inflating the pole and begins the shrink, as shown in fig. 7 to the effect of increase drive blade revolving force has been reached.)

1. The utility model provides an utilize revolving force to increase wind power generation equipment who receives amount of wind, includes pole setting (1), its characterized in that: the surface swing joint of pole setting (1) has pivot (2), and axle sleeve (3) have been cup jointed on the surface of pivot (2), and the fixed surface of axle sleeve (3) is connected with blade (4), and the inside fixedly connected with connecting rod (5) of blade (4).

The surface swing joint of connecting rod (5) has gear (6), and the surface meshing of gear (6) has rotor (7), and the inside swing joint of rotor (7) has deviation wheel (8), and the fixed surface of rotor (7) is connected with damper plate (9), and the surface of damper plate (9) articulates there is wind vane (10).

2. A wind power generation apparatus for increasing an amount of wind received by using a rotational force according to claim 1, wherein: the inside of the damping plate (9) is movably connected with a spring rod (11).

3. A wind power generation apparatus for increasing an amount of wind received by using a rotational force according to claim 2, wherein: one end of the spring rod (11) far away from the damping plate (9) is movably connected with a deformation bag (12).

4. A wind power generation apparatus for increasing an amount of wind received by using a rotational force according to claim 3, wherein: the surface of the deformation bag (12) is fixedly connected with an inflation rod (13).

5. A wind power generation apparatus for increasing an amount of wind received by using a rotational force according to claim 1, wherein: the spring rod (11) is movably connected with the damping plate (9) through a base (14).

6. A wind power generation apparatus for increasing an amount of wind received by using a rotational force according to claim 1, wherein: the surface of the deformation bag (12) is sleeved with a limit box (15).

7. A wind power generation apparatus for increasing an amount of wind received by using a rotational force according to claim 1, wherein: the rotor (7) is designed as three circles.

8. A wind power generation apparatus for increasing an amount of wind received by using a rotational force according to claim 1, wherein: the number of the blades (4) is three.

Technical Field

The invention relates to the technical field of wind power generation, in particular to a wind power generation device for increasing air receiving capacity by utilizing rotating force.

Background

With the rapid increase of the population of the earth, the number of non-renewable energy sources is less, so that equipment capable of utilizing natural energy sources is developed, wherein wind power generation refers to equipment for converting kinetic energy of wind into electric energy.

Existing wind power generation equipment is mostly arranged at an open position with large wind power, strong wind blows on the surface of a fan blade to enable the fan blade to rotate around a rotating shaft, and force generated by rotation of the fan blade is used for driving a power generation component in the wind power generation equipment so as to convert wind energy into electric energy.

Although traditional wind power generation set can effectually utilize wind energy, but because its volume is great, only can blow it when wind-force reaches certain intensity, but when meetting the weather that wind-force is more weak, then can't effectually utilize it, in addition, the last blade of current wind power generation set, can blow the flabellum rotatory when meetting the downwind, but can resist the rotation of flabellum when meetting the upwind, its self does not have corresponding equipment that can increase the windage and reduce the windage, lead to it to sometimes hinder wind power generation set's rotation, consequently a wind power generation equipment that utilizes the revolving force to increase the volume of receiving wind takes place.

Disclosure of Invention

In order to achieve the purposes of automatically adjusting wind resistance and increasing the rotating force of the driving blade, the invention provides the following technical scheme: the utility model provides an utilize revolving force to increase wind power generation equipment who receives the amount of wind, includes the pole setting, the surperficial swing joint of pole setting has the pivot, and the axle sleeve has been cup jointed on the surface of pivot, and the fixed surface of axle sleeve is connected with the blade, the inside fixedly connected with connecting rod of blade, the surperficial swing joint of connecting rod has the gear, and the surface meshing of gear has the rotor, and the inside swing joint of rotor has the deviation wheel, and the fixed surface of rotor is connected with the shock attenuation board, and the surface of shock attenuation board articulates.

The invention has the beneficial effects that:

1. by connecting the rotor and the connecting rod in the blade through the gear, when the blade is blown by wind, the blade can deflect in the direction without wind force or with small wind force, meanwhile, the rotor is blown by one side with large wind force, the meshing gear rotates on the surface of the connecting rod and rotates in the opposite direction of the wind force, namely, the wind direction plate faces the wind-receiving surface, the wind force enters the inside of the deformation bag, the deformation bag is blown to expand and enlarge, and the inflation rod on the surface of the deformation bag is also expanded and enlarged to push the wind direction plate to expand towards two sides, as shown in figure 5, when the blade rotates to the wind-free surface, the positions of the rotor and the wind direction plate are unchanged, at the moment, the wind direction plate loses the wind-blowing force, the force blown in the air before the release is started, namely, a force for pushing the blade to rotate is generated, and in the release process, the supporting force of the inflation rod of the wind direction plate begins to shrink, as, thereby achieving the effect of increasing the rotating force of the driving blade.

2. When the blades are blown by wind power, the deformation bag and the inflation rod expand to be enlarged, the wind direction plate is blown, the stress area of the blades is enlarged, when the blades rotate to the wind-free surface, the deformation bag and the inflation rod release the air flow, and the wind direction plate is driven to gradually contract, so that the stress area of the blades is reduced, and the effect of automatically adjusting wind resistance is achieved.

Preferably, the spring rod is movably connected inside the damping plate, and the spring rod can buffer the force of the limiting box impacting the blade when the wind power is too large.

Preferably, one end of the spring rod, which is far away from the damping plate, is movably connected with a deformation bag.

Preferably, the surface of the deformation capsule is fixedly connected with an inflation rod.

Preferably, the spring rod is movably connected with the damping plate through the base.

Preferably, the surface of the deformation bag is sleeved with a limit box.

Preferably, the rotor is formed in three circles, and is designed to increase the blowing range of the received wind so that it can rotate regardless of the direction of the force applied thereto, but the force is greater than the force applied to engage with the gear.

Preferably, the number of the blades is three, and each blade is internally provided with four rotating bodies.

Drawings

FIG. 1 is a schematic view of a rotating shaft structure according to the present invention;

FIG. 2 is a schematic view of a blade configuration according to the present invention;

FIG. 3 is a schematic view of the combination of the wind direction plate structure and the shock absorbing plate structure of the present invention being blown up;

FIG. 4 is a sectional view showing the structure of a rotor according to the present invention;

FIG. 5 is a schematic view of the present invention showing the louver structure being blown up;

FIG. 6 is a schematic view of the combination of the wind direction plate structure and the shock absorbing plate structure of the present invention;

FIG. 7 is a schematic view of the wind deflector structure of the present invention when it is not being blown up.

In the figure: 1-upright rod, 2-rotating shaft, 3-shaft sleeve, 4-blade, 5-connecting rod, 6-gear, 7-rotor, 8-deflection wheel, 9-damping plate, 10-wind direction plate, 11-spring rod, 12-deformation bag, 13-inflation rod, 14-base and 15-limit box.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-7, a wind power generation apparatus for increasing a wind receiving capacity by using a rotational force, comprising a vertical rod 1, a rotating shaft 2 movably connected to a surface of the vertical rod 1, a shaft sleeve 3 sleeved on a surface of the rotating shaft 2, a blade 4 fixedly connected to a surface of the shaft sleeve 3, a connecting rod 5 fixedly connected to an inside of the blade 4, a gear 6 movably connected to a surface of the connecting rod 5, a rotor 7 engaged with a surface of the gear 6, three blades 4, and four rotors 7 arranged inside each blade 4, wherein when the blade 4 is blown by the wind, the blade can deflect in a direction not receiving the wind force or having a smaller wind force, and at the same time, the rotor 7 is blown by a side having a larger wind force, and when the rotor 7 is blown by the wind, a deflection wheel 8 inside the rotor 7 can be stacked at a lower end of the rotor 7 to increase a deflection force of the rotor 7, the, the design is to enlarge the blowing range of the received wind direction, so that the wind-driven generator can rotate no matter which direction the wind-driven generator receives, but the force needs to be larger than the force of the wind-driven generator and the gear 6 which are meshed, the inner part of the rotor 7 is movably connected with a deviation wheel 8, the surface of the rotor 7 is fixedly connected with a damping plate 9, the inner part of the damping plate 9 is movably connected with a spring rod 11, one end of the spring rod 11, which is far away from the damping plate 9, is movably connected with a deformation bag 12, the surface of the deformation bag 12 is fixedly connected with an inflation rod 13, the spring rod 11 is movably connected with the damping plate 9 through a base 14, the surface of the deformation bag 12 is sleeved with a limit box 15, the limit box 15 plays a role of buffering the force of impacting the blade 4 when the wind power is too large, the surface of the damping plate 9 is hinged with a wind direction plate 10, the wind direction plate 10 faces the wind power to the, pushing the wind direction plate 10 to spread to both sides, as shown in fig. 5; when the blades 4 rotate to the non-wind-surface, the deformation bag 12 and the inflation rod 13 release the previous air flow and drive the wind direction plate 10 to gradually contract, so that the stress area of the blades 4 is reduced; when the blades 4 are subjected to clockwise or counterclockwise wind, the rotor 7 can be biased to be not subjected to the wind.

When in use, the rotator 7 is connected with the connecting rod 5 in the blade 4 through the gear 6, when the blade 4 is blown by wind, the blade can deflect in the direction without wind force or with smaller wind force, meanwhile, the rotator 7 is blown by the side with larger wind force, when the rotator 7 is blown by wind, the deflection wheel 8 in the rotator 7 can be accumulated at the lower end of the rotator 7 to play a role in increasing the deflection force of the rotator 7, the meshing gear 6 rotates on the surface of the connecting rod 5 and rotates in the opposite direction of the wind force, namely, the wind vane 10 faces the wind-receiving surface, the wind force enters the deformation bag 12 to expand the deformation bag 12 by blowing, and drive the inflation rod 13 on the surface to expand and increase, and push the wind vane 10 to expand towards two sides, as shown in fig. 5, when the blade 4 rotates to the wind-receiving surface, the positions of the rotator 7 and the wind vane 10 are unchanged, and at the moment, the wind vane 10 loses the wind-blowing force, the force blown by the air before the release is started, namely, a force pushing the blades 4 to rotate is generated, and in the release process, the wind direction plate 10 loses the supporting force of the air inflation rod 13 and begins to contract, as shown in fig. 7, the function of increasing the rotating force of the driving blades 4 is realized; when the blades 4 are blown by wind, the deformation bag 12 and the inflation rod 13 expand to be enlarged, the wind deflector 10 is blown, the stress area of the blades 4 is increased, when the blades 4 rotate to the wind-free surface, the deformation bag 12 and the inflation rod 13 release the previous air flow, and the wind deflector 10 is driven to gradually contract, so that the stress area of the blades 4 is reduced, and the effect of automatically adjusting the wind resistance of the blades 4 is achieved.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be able to cover the technical scope of the present invention and the equivalent alternatives or modifications according to the technical solution and the inventive concept of the present invention within the technical scope of the present invention.