CN207195091U - A kind of dynamic power machine strength accelerates three ring electricity generation systems of reinforcing - Google Patents

Abstract

It the utility model is related to a kind of energy saver, and in particular to a kind of dynamic power machine strength accelerates three ring electricity generation systems of reinforcing, including windmill, speed changer, mechanical group and generator, and the windmill drives the machinery group to drive the electrical power generators by the speed changer；The machinery group includes at least two groups of mechanical wheels, every group of mechanical wheel includes bearing bracket stand, axle is provided with the bearing bracket stand, flywheel, flying wheel and transmission gear shift wheel are sequentially provided with the axle from top to bottom, the flywheel and the flying wheel tight fit connection, the flying wheel is fixedly connected with the transmission gear shift wheel, using transmission band connection between the mechanical wheel.The utility model sets mechanical group before generator, it is possible to increase the efficiency of mechanical energy conversion, reaches the purpose of energy-conserving and environment-protective.

Description

A three-ring power generation system with strong acceleration and afterburner for power machinery

technical field

The utility model relates to an energy-saving device, in particular to a three-ring power generation system with powerful acceleration and afterburning for power machinery.

Background technique

With the development of science and the progress of human beings, energy saving, environmental protection, high efficiency and low consumption are the urgent situation and needs in front of people in the process of power generation. Power generation efficiency is a current technical problem.

The technology of converting wind energy into kinetic energy has been mature in ancient times. With the wisdom of the working people, wind power can replace livestock power and manpower, which not only ensures safety, but also improves work efficiency. water irrigation, seawater salt production, etc. Converting wind energy into kinetic energy is far from meeting the needs of modern people. Converting wind energy into electrical energy can maximize resource utilization and meet the needs of modern people. At the same time, the advantage of wind power generation is energy saving and environmental protection. Wind power is a clean natural energy without the environmental pollution problems associated with coal power, oil power and nuclear power. Moreover, wind power is a renewable energy source. To develop renewable energy, combine it with The combination of improving energy efficiency will make a major contribution to global economic development, solving the energy problems of the poor, and reducing greenhouse gas emissions.

Of course, in the process of using wind power to generate electricity, the conversion of wind energy requires certain equipment. Due to the limitations of the equipment itself, it is impossible to convert all the energy into the energy that people need.

Utility model content

The utility model provides a three-ring power generation system with strong acceleration and afterburning of power machinery. The power machinery acceleration and afterburning energy-saving machine is applied to the power generation system, which can achieve the purpose of energy saving and environmental protection.

A three-loop power generation system with powerful acceleration and afterburner for power machinery, including a windmill, a transmission, a mechanical group and a generator, the windmill drives the mechanical group through the transmission to drive the generator to generate electricity; the mechanical group includes at least two A set of mechanical wheels, each set of mechanical wheels includes a bearing frame, the bearing frame is provided with a shaft, and the shaft is sequentially provided with a flywheel, an inertia wheel and a transmission speed change wheel from top to bottom, and the flywheel and the inertia wheel Tight fit connection, the inertia wheel is fixedly connected with the transmission speed change wheel, and the mechanical wheels are connected by a transmission belt.

Further, the mechanical group includes a first mechanical wheel and a second mechanical wheel, and the two sets of mechanical wheels are arranged in opposite directions. By setting two sets of mechanical wheels arranged in opposite directions, when the windmill drives the first mechanical wheel of the mechanical set to rotate through the transmission, the first mechanical wheel then drives the second mechanical wheel to rotate.

Further, the transmission belt includes a first transmission belt, and the two ends of the first transmission belt are respectively wound on the first transmission speed change wheel and the second flywheel. By setting the first transmission belt, the windmill drives the first flywheel in the first mechanical wheel of the mechanical group to rotate through the transmission. When the first flywheel rotates, it drives the first inertia wheel closely matched with it to rotate. When the first inertia wheel rotates, it drives the second flywheel. The first transmission speed change wheel rotates, and when the first transmission speed change wheel rotates, it drives the first transmission belt to rotate, thereby driving the second mechanical wheel to rotate.

Further, the mechanical group includes a first mechanical wheel, a second mechanical wheel and a third mechanical wheel, the first mechanical wheel and the third mechanical wheel are arranged in a forward direction, and the second mechanical wheel is arranged in a reverse direction. By setting the three mechanical wheels, when the windmill drives the first mechanical wheel to rotate through the transmission, the first mechanical wheel drives the second mechanical wheel to rotate, and the second mechanical wheel drives the third mechanical wheel to rotate.

Further, the transmission belt includes a first transmission belt and a second transmission belt, the two ends of the first transmission belt are respectively wound on the first transmission transmission wheel and the second flywheel, and the two ends of the second transmission belt are respectively wound on the second transmission transmission wheel and the third flywheel superior. By setting the first transmission belt and the second transmission belt, the windmill drives the first flywheel in the first mechanical wheel of the mechanical group to rotate through the transmission. When the first flywheel rotates, it drives the first inertia wheel closely matched with it to rotate, and the first inertia wheel rotates. At the same time, it drives the first transmission speed change wheel to rotate. When the first transmission speed change wheel rotates, it drives the first transmission belt to rotate. The first transmission belt drives the second flywheel of the second mechanical wheel to rotate, and the second flywheel drives the second inertia wheel that is closely matched with it to rotate. , when the second inertia wheel rotates, it drives the second transmission speed change wheel to rotate, and when the second transmission speed change wheel rotates, it drives the second transmission belt to rotate, thereby driving the third mechanical wheel to rotate.

The beneficial effects that the utility model can produce are as follows:

1. In this utility model, a mechanical group is arranged in front of the generator, which can improve the efficiency of mechanical energy conversion and achieve the purpose of energy saving and environmental protection.

2. The utility model utilizes a mechanical group to buffer the sudden change of speed transmitted by the windmill, and then buffers the speed of the generator to avoid damage to the generator caused by the sudden change of mechanical energy, reduce the probability of damage to the generator, and prolong its service life.

Description of drawings

Fig. 1 is a block diagram of the utility model;

Fig. 2 is a structural schematic diagram of the mechanical group in the utility model.

In the figure: 1-bearing frame, 2-shaft, 3-first flywheel, 4-first inertia wheel, 5-first transmission speed change wheel, 6-first transmission belt, 7-second flywheel, 8-second inertia Wheel, 9-second transmission speed change wheel, 10-second transmission belt, 11-windmill, 12-transmission, 13-mechanical group, 13-1-first mechanical wheel, 13-2-second mechanical wheel, 13-3 - Third mechanical wheel, 14 - Generator.

Detailed ways

The utility model will be further described in detail below in conjunction with the accompanying drawings and specific embodiments, but the protection scope of the utility model is not limited thereto.

As shown in Figures 1 and 2, a three-ring power generation system with powerful acceleration and afterburner for power machinery is characterized in that it includes a windmill 11, a transmission 12, a mechanical group 13 and a generator 14, and the windmill 11 is driven by the transmission 12. The mechanical group 13 drives the generator 14 to generate electricity. The mechanical group 13 includes three sets of mechanical wheels, respectively the first mechanical wheel 13-1, the second mechanical wheel 13-2 and the third mechanical wheel 13-3, the first mechanical wheel 13-1 and the third mechanical wheel 13 -3 is set in the forward direction, and the second mechanical wheel 13-2 is set in the opposite direction. By setting these three sets of mechanical wheels, when the windmill 11 drives the first mechanical wheel 13-1 of the mechanical set to rotate through the transmission 12, the first mechanical wheel 13-1 drives the second mechanical wheel 13-2 Rotate, the second mechanical wheel 13-2 drives the third mechanical wheel 13-3 to rotate again.

Each group of mechanical wheels includes a bearing frame, on which a shaft is arranged, and a flywheel, an inertia wheel and a transmission speed change are set on the shaft. The working principle of the flywheel is the same as that of a bicycle flywheel. The mating connection can drive the inertia wheel shaft to rotate together, and when it rotates in another direction, it is disengaged from the inertia wheel shaft and cannot drive the inertia wheel shaft to rotate. The inertia wheel is closely matched with the flywheel, and the transmission speed change wheel is fixedly connected with the inertia wheel. The transmission belt comprises a first transmission belt 6 and a second transmission belt 10, the two ends of the first transmission belt 6 are respectively wound on the first transmission transmission wheel 5 and the second flywheel 7, and the two ends of the second transmission belt 10 are respectively wound on the second transmission transmission wheel 9 and the third flywheel. The windmill 11 drives the first flywheel 3 of the first mechanical wheel 13-1 to rotate through the transmission 12, thereby driving the three sets of mechanical wheels to rotate. The first mechanical wheel 13-1 includes a bearing frame 1. A shaft 2 is arranged on the bearing frame 1. A flywheel is sleeved on the shaft 2. On the shaft 2, a first flywheel 3 and a first inertia wheel are sequentially arranged from top to bottom. Wheel 4 and the first transmission speed change wheel 5, the first flywheel 3 and the first inertia wheel 4 are tightly connected, and the first inertia wheel 4 is fixedly connected with the first transmission speed change wheel 5. The adjacent two sets of mechanical wheels in the mechanical group 13 are connected by a transmission belt, and the first mechanical wheel 13-1 and the second mechanical wheel 13-2 are connected by a first transmission belt 6, and the first transmission belt 6 is connected to the second flywheel 7 of the second mechanical wheel b through the first transmission speed change wheel 5 of the first mechanical wheel 13-1. In the second mechanical wheel 13-2, the second transmission speed change wheel 9, the second inertia wheel 8 and the second flywheel 7 are sequentially arranged from top to bottom. The mechanical configuration of the third mechanical wheel 13-3 is the same as that of the first mechanical wheel 13-1. The windmill 11 drives the first flywheel 3 of the first mechanical wheel 13-1 of the mechanical group 13 to rotate through the speed changer 12, and simultaneously drives the first inertial wheel 4 closely matched with it to rotate, and the first inertial wheel 4 rotates while driving the first transmission speed change When the wheel 5 rotates, the first transmission speed change wheel 5 drives the first transmission belt 6 to rotate, and the transmission belt 6 drives the second flywheel 7 of the second mechanical wheel 13-2 to rotate, and the second flywheel 7 of the second mechanical wheel b rotates Drive the second inertia wheel 8 that is closely matched with it to rotate, drive the second transmission speed change wheel 9 to rotate when the second inertia wheel 8 rotates, drive the third transmission belt 10 to rotate when the second transmission speed change wheel 9 of the second mechanical wheel 13-2 rotates , thereby driving the third mechanical wheel 13-3 to rotate.

The windmill 11 converts wind energy into mechanical energy. The transmission 12 drives the mechanical group 13 to run through the transmission belt after changing the speed and torque of the windmill 11. Finally, the mechanical group 13 transmits the mechanical energy to the generator 14 to drive the generator 14 to generate electricity. When the wind power is not enough to drive the windmill 11 to rotate, the windmill 11 no longer transmits mechanical energy to the mechanical group 13. At this time, the mechanical group 13 relies on the mechanical energy stored in the previous time to rotate and transmit the corresponding mechanical energy to the generator 14. The mechanical group 13 can Effectively use the inertia of its own rotation to buffer the sudden change in the power generation of the generator 14; when the wind is strong, the mechanical energy provided by the windmill 11 to the mechanical group 13 is relatively large, and the mechanical group 13 can effectively use its own mechanical wheels to transfer the instantaneous large mechanical energy Decompose the buffer into uniform mechanical energy, and then drive the generator 14 to generate electricity evenly. The mechanical group 13 can effectively store and release corresponding energy, effectively improve the conversion efficiency of mechanical energy, and achieve the purpose of energy saving and environmental protection.

The flywheel is a device with a self-clutching function utilizing the transformation of the rotation direction of the main and driven parts. When the flywheel and the inertia wheel rotate in one direction, the flywheel and the inertia wheel shaft are tightly connected, and the flywheel can drive the inertia wheel shaft to rotate together. When the rotation directions of the flywheel and the inertia wheel are inconsistent, the flywheel and the inertia wheel shaft are disengaged, and the flywheel It cannot drive the inertia wheel shaft to rotate.

It should be noted that the above-mentioned embodiment is an illustration of the technical solution of the utility model rather than a limitation, equivalent replacements by those of ordinary skill in the art or other modifications made according to the prior art, as long as they do not exceed the thinking of the technical solution of the utility model and scope should be included in the scope of rights required by the utility model.

Claims (5)

1. A three-ring power generation system with powerful acceleration and afterburner for power machinery, comprising a windmill, a transmission, a mechanical group and a generator, and the windmill drives the mechanical group through the transmission to drive the generator to generate electricity; the mechanical group includes At least two groups of mechanical wheels, each group of mechanical wheels includes a bearing frame, the bearing frame is provided with a shaft, and the shaft is sequentially provided with a flywheel, an inertia wheel and a transmission speed change wheel from top to bottom, and the flywheel and the The inertia wheel is tightly fitted and connected, and the inertia wheel is fixedly connected with the transmission transmission wheel, and the mechanical wheels are connected by a transmission belt. 2. A three-loop power generation system with powerful acceleration and afterburning for power machinery according to claim 1, wherein the mechanical group includes a first mechanical wheel and a second mechanical wheel, and the two sets of mechanical wheels are arranged in opposite directions. 3. A three-loop power generation system with strong acceleration and afterburning for power machinery according to claim 1, wherein the transmission belt comprises a first transmission belt, and the two ends of the first transmission belt are respectively wound on the first transmission speed change wheel and the second transmission wheel. on flywheel. 4. A three-ring power generation system with powerful acceleration and afterburning for power machinery according to claim 1, wherein the mechanical group includes a first mechanical wheel, a second mechanical wheel and a third mechanical wheel, and the first The mechanical wheel and the third mechanical wheel are arranged in a positive direction, and the second mechanical wheel is arranged in a reverse direction. 5. A three-loop power generation system with strong acceleration and afterburning for power machinery according to claim 4, wherein the transmission belt includes a first transmission belt and a second transmission belt, and the two ends of the first transmission belt are respectively wound on the first transmission belt. On the transmission speed change wheel and the second flywheel, the two ends of the second transmission belt are respectively wound on the second transmission speed change wheel and the third flywheel.