TWM620708U - Mobile solar power generation mechanism - Google Patents

Abstract

A mobile solar power generation mechanism includes a solar panel, a first lifting mechanism, a rail car, a rail platform, and a second lifting mechanism. The first lifting mechanism is located at the bottom of the solar panel and is used to adjust the inclination angle of the solar panel. The rail car is located at the bottom of the first lifting mechanism and is used to carry the first lifting mechanism. The rail platform is located under the rail car to provide a moving space for the rail car. The second lifting mechanism is located at the bottom of the track platform and is used to adjust the inclination angle of the track platform.

Description

Mobile solar power generation mechanism

This creation is about a solar power generation mechanism, especially a mobile solar power generation mechanism.

Solar power generation is one of the main sources of electricity in the future, and is currently the main renewable energy solution recommended by the government. One way of fishery and electricity symbiosis is to use floating platform solar panels to be built on the water surface of the fishery and aquaculture ponds. However, observations in recent years have found that migratory birds will inhabit the floating platform solar panels, leaving pollutants such as feces on the surface of the solar panels, affecting the power generation efficiency of the solar panels.

Another way is to install solar panels above the breeding pond. However, due to the huge overall structure and the shading area, it will affect the growth of the original ecology, and there are also the cleaning problems of solar panels, which hinder the promotion of fishery and electricity symbiosis.

Therefore, how to improve and provide a "mobile solar power generation mechanism" to avoid the above-mentioned problems is an important issue in the industry.

In view of the above-mentioned problems of learning skills, one of the purposes of this creation is to provide a mobile solar power generation mechanism to solve various problems of learning skills.

According to one of the objectives of this creation, a mobile solar power generation mechanism is proposed, which includes a solar panel, a first lifting mechanism, a rail car, a rail platform, and a second lifting mechanism. The first lifting mechanism is located at the bottom of the solar panel and is used to adjust the inclination angle of the solar panel. The rail car is located at the bottom of the first lifting mechanism and is used to carry the first lifting mechanism. The rail platform is located below the rail car, and is used to provide a moving space for the rail car. The second lifting mechanism is located at the bottom of the track platform and is used to adjust the inclination angle of the track platform.

In order to make this creation more obvious and easy to understand, the following examples are specially cited, and the accompanying drawings are described in detail as follows.

For the sake of clarity and convenience for the description of the drawings, the various components in the drawings may be displayed in an enlarged or reduced scale in terms of size and proportion. In the following description and/or the scope of the patent application, when an element is referred to as being “connected” or “coupled” to another element, it can be directly connected or coupled to the other element or an intervening element may be present; and when referring to an element When "directly connected" or "directly coupled" to another element, there is no intervening element, and other words used to describe the relationship between elements or layers should be interpreted in the same way. Ordinal numbers such as "first" and "second" do not have a sequential relationship with each other, and they are only used to mark two different elements with the same name. To facilitate understanding, the same elements in the following embodiments are described with the same symbols.

Please refer to Figure 1A, which is a schematic diagram of the solar panel mechanism of the first embodiment of this creation. As shown in FIG. 1A, the first solar panel 10 is located on the first lifting mechanism 20. The first lifting mechanism 20 is located on the rail car 30. The rail car 30 is located on the rail platform 50. The reels 40 are respectively arranged on both sides of the rail car 30. The reel 40 is connected to both sides (front end and rear end) of the rail car 30 through cables 42 respectively. The two first lifting mechanisms 20 at the bottom of the first solar panel 10 both have a telescopic support rod structure. In some embodiments, the first lifting mechanism 20 at the bottom of the first solar panel 10 may have a telescopic support rod structure on only one side.

A first sprayer 12 is installed at one end of the first solar panel 10. The bottom of the first solar panel 10 is connected to the first lifting mechanism 20. In one embodiment, the first lifting mechanism 20 is vertically arranged on the plane of the rail car 30, or may be arranged at other angles. The rail car 30 is located at the bottom of the first lifting mechanism 20 and is used to carry the first lifting mechanism 20.

The rail car 30 has an embedded axle 32. The rail car 30 moves on the rail platform 50 through the embedded wheel axle 32. In fact, the embedded axle 32 is embedded in the track of the track platform 50.

Please refer to Figure 1B, which is a schematic diagram of the solar panel mechanism of the second embodiment of this creation. As shown in Figure 1B, the difference between the second embodiment of the present creation and the first embodiment is that: the first solar panel 10 of the second embodiment is provided with a first sprayer 12 and a second sprayer 14 at both ends of the first solar panel 10, respectively. .

In some embodiments, the first sprayer 12 can use foam cleaner to spray and clean the surface of the first solar panel 10, and the second sprayer 14 can use clean water to spray and clean the surface of the first solar panel 10. , The outlets of the first sprayer 12 and the second sprayer 14 face the surface of the first solar panel 10. In some embodiments, the second sprayer 14 can use a foam cleaner to spray and clean the surface of the first solar panel 10, and the first sprayer 12 can use clean water to spray and clean the surface of the first solar panel 10. . In some embodiments, when the size of the first solar panel 10 is larger, the second sprayer 14 needs to be installed to spray and clean the surface of the first solar panel 10 in cooperation with the first sprayer.

In some embodiments, when the inclination angle of the first solar panel 10 is high left and low right, the second sprayer 14 can be activated to spray and clean the first solar panel 10, so that the sewage 70 naturally flows to the lower part. And collect. In some embodiments, when the inclination angle of the first solar panel 10 is low left and high right, the first sprayer 12 can be activated to spray and clean the first solar panel 10, so that the sewage 70 naturally flows to the lower place. And collect. In some embodiments, the two first lifting mechanisms 20 at the bottom of the first solar panel 10 both have a telescopic support rod structure to provide more tilt angle adjustment functions.

Please refer to Figure 2A, which is a schematic diagram of the mechanism of the first embodiment of this creation. As shown in FIG. 2A, the mobile solar power generation mechanism 100 includes a first solar panel 10, a first lifting mechanism 20, a rail car 30, a reel 40, a rail platform 50 and a second lifting mechanism 60.

The first solar panel 10 is used to convert the radiant energy of the sun 200 into electrical energy. In fact, the first solar panel 10 can be composed of photoelectric semiconductors, batteries, frequency converters, and other parts, such as monocrystalline silicon, polycrystalline silicon, CdTe thin film batteries, CIGS thin film batteries, dye-sensitized thin film batteries, organic material batteries, etc. The power generation amount of the first solar panel 10 is proportional to the sunshine time and the sunshine intensity of the sun 200. The surface of the first solar panel 10 has a nano-coating to reduce the adhesion of pollutants. In some embodiments of the present invention, the first sprayer 12 is located at one end of the first solar panel 10. The outlet of the first sprayer 12 faces the first solar panel 10 for spraying and cleaning the surface of the first solar panel 10.

The first lifting mechanism 20 is located at the bottom of the first solar panel 10. The first lifting mechanism 20 is used to adjust the inclination angle of the first solar panel 10. More specifically, the first lifting mechanism 20 is located between the bottom of the first solar panel 10 and the rail car 30. The first lifting mechanism 20 has a telescopic support rod to adjust the inclination angle of the first solar panel 10 from 0 degrees to 45 degrees (relative to the horizontal plane). In fact, the first lifting mechanism 20 can be composed of a hydraulic or pneumatic telescopic support rod.

The rail car 30 is located at the bottom of the first lifting mechanism 20. More specifically, the upper surface of the rail car 30 is connected to the bottom of the first lifting mechanism 20 (for example, a fixing method such as locking or welding). The rail car 30 is used to carry the first lifting mechanism 20.

In addition, the second solar panel 10a is located beside the first solar panel 10, and the first lifting mechanism 20 and the rail car 30 are also installed. In Figure 2A, two sets of solar panels are used as an example, not to limit the number of solar panels. In some embodiments of this creation, the number of solar panels can be adjusted according to requirements.

The reel 40 is used to control the speed and distance of the rail car 30 moving on the rail platform 50. It is worth mentioning that the design of the reel 40 and the cable 42 enables the rail car 30 to move on the rail platform 50 in a gentle sliding manner.

The rail platform 50 is located below the rail car 30. The rail platform 50 is used to provide a moving space for the rail car 30. The rail car 30 moves on the rail platform 50 through an embedded axle 32 (as shown in FIG. 2A).

The second lifting mechanism 60 is located at the bottom of the track platform 50. The second lifting mechanism 60 is used to adjust the inclination angle of the track platform 50. More specifically, the second lifting mechanism 60 is located at the bottom of the track platform 50 and is erected above the breeding pond 90. The second lifting mechanism 60 has a telescopic support rod to adjust the inclination angle of the track platform 50 from 0 degrees to 45 degrees (relative to the horizontal plane). In fact, the second lifting mechanism 60 can be composed of a hydraulic or pneumatic telescopic support rod.

As shown in Figure 2A, when the sun 200 rises to the first position, the second lifting mechanism 60 adjusts the telescopic support rods to different heights from left to right, so that the inclination angle of the track platform 50 is left high Low right state. In this way, the rail car 30 can naturally slide to the right through gravity. Therefore, there is no need to control the movement of the rail car 30 through additional motor equipment, which not only reduces the construction cost of the mobile solar power generation mechanism 100, but also relatively reduces the mobile solar power generation. The difficulty of the establishment of 100 institutions.

In addition, the design of the reel 40 and the cable 42 can reduce the sliding force of the rail car 30 when moving on the rail platform 50, thereby avoiding the situation that the rail cars 30 collide with each other due to high-speed sliding and cause damage. In one embodiment, the reel 40 is connected to multiple groups of first solar panels 10 at the same time through the cable 42, or a single reel 40 is used to connect a single first solar panel 10.

In some embodiments of the present invention, a sewage collection platform 62 is located on the second lifting mechanism 60 for collecting sewage 70 after cleaning the first solar panel 10. In some embodiments of the present invention, the sewage collection platform 62 may also be omitted. A sewage discharge pipeline 80 is located in the second lifting mechanism 60. The sewage discharge pipeline 80 extends from the bottom of the track platform 50 to the sewage collection platform 62 to discharge the sewage 70 after cleaning the first solar panel 10. In this way, the pollution of the breeding pond 90 by the sewage 70 can be avoided.

It is worth mentioning that after the first sprayer 12 sprays and cleans the surface of the first solar panel 10, the sewage 70 will be discharged through the sewage discharge pipe 80. Since the inclination angle of the track platform 50 is in the left-high and right-low relationship, the sewage 70 can naturally flow to the sewage collection platform 62 and the sewage discharge pipeline 80 through gravity, without the need to install additional drainage motor equipment, which can also be reduced The construction cost of the mobile solar power generation mechanism 100.

Please refer to Figure 2B, which is a schematic diagram of another mechanism in the first embodiment of the creation. As shown in Figure 2B, when the sun 200 rises to the second position, the second lifting mechanism 60 adjusts the telescopic support rods from left to right to form different heights, so that the inclination angle of the track platform 50 is lower to the left State of high right. In this way, the rail car 30 can naturally slide to the left through gravity.

Similarly, after the first sprayer 12 sprays and cleans the surface of the first solar panel 10, the sewage 70 will be discharged through the sewage discharge pipe 80. Since the inclination angle of the track platform 50 is low in the left and high in the right, the sewage 70 can naturally flow to the sewage collection platform 62 and the sewage discharge pipeline 80 through gravity.

Please refer to Figure 2C, which is a schematic diagram of another mechanism in the first embodiment of the creation. As shown in Figure 2C, when the sun 200 rises to the third position, the first lifting mechanism 20 adjusts the telescopic support rods to different heights from left to right, so that the first solar panel 10 and the second solar panel 10 The inclination angle of 10a presents a state of high left and low right. In this way, not only can the shading range of the first solar panel 10 and the second solar panel 10a be changed, but also the first solar panel 10 and the second solar panel 10a can be adjusted to have a better light absorption angle, and the power generation efficiency can be improved.

The second lifting mechanism 60 adjusts the telescopic support rods to different heights from left to right, so that the inclination angle of the track platform 50 presents a state of high left and low right. In this way, the rail car 30 can naturally slide to the right through gravity.

Therefore, it can be seen from FIGS. 2A to 2C that the second lifting mechanism 60 adjusts the position of each solar panel on the track platform 50 in this creative embodiment, thereby changing the shading range of each solar panel to avoid affecting breeding The original ecology of the pool 90. In addition, in this creative embodiment, the first lifting mechanism 20 can also adjust the inclination angle of each solar panel according to the position of the sun 200, thereby improving the power generation efficiency.

In summary, according to the embodiment of this creation, the surface of the solar panel of the mobile solar power generation mechanism has a nano-coating, and sprayers are installed. The nano-coating can effectively reduce the sticking to the surface of the solar panel. The adhesion of bird droppings and pollutants, and the sprayer can spray to clean the surface of solar panels, so it can avoid the trouble of bird droppings and pollutants sticky and difficult to clean, so that the surface of solar panels can be easily kept clean.

According to the embodiment of this creation, the surface of the solar panel of the mobile solar power generation mechanism has a nano-coating, and is equipped with sprayers, so that the surface of the solar panel can be easily kept clean, so it can prevent the surface of the solar panel from being dirty. Affect the power generation efficiency of solar panels to avoid sewage pollution of the breeding pond.

According to the embodiment of this creation, the mobile solar power generation mechanism integrates solar panels, lifting mechanism, rail car and rail car platform through clever mechanism design, so it can effectively use gravity to make solar panels easy to move and clean, and It can improve the convenience of sewage discharge.

According to the embodiment of this creation, the mobile solar power generation mechanism integrates solar panels, lifting mechanism, rail car and rail car platform, and has an independent sewage collection platform and sewage discharge pipeline, which can adjust the inclination angle of the track platform The sewage flows naturally to the sewage collection platform and sewage discharge pipeline through gravity, without the need to install additional drainage motor equipment, so the construction cost of the mobile solar power generation mechanism can be reduced.

According to the embodiment of this creation, the mobile solar power generation mechanism integrates solar panels, lifting mechanisms, rail cars and rail car platforms through a special mechanism design, so the shade range of the solar panels can be dynamically adjusted to avoid affecting the original ecology of the breeding pond .

The above description uses the preferred embodiments to illustrate the creation in detail, and does not limit the scope of the creation. Anyone who is familiar with this kind of art can understand that if appropriate and slight changes and adjustments are made, the essence of this creation will not be lost, nor will it deviate from the spirit and scope of this creation.

10: The first solar panel 10a: Second solar panel 12: The first sprayer 14: Second sprayer 20: The first lifting mechanism 30: Railcar 32: Embedded Axle 40: Scroll 42: Cable 50: Orbital platform 60: The second lifting mechanism 62: Sewage collection platform 70: sewage 80: Sewage discharge pipeline 90: Breeding pond 100: Mobile solar power generation mechanism 200: Sun

Figure 1A is a schematic diagram of the solar panel mechanism of the first embodiment of the creation. Figure 1B is a schematic diagram of the solar panel mechanism of the second embodiment of the creation. Figure 2A is a schematic diagram of the mechanism of the first embodiment of the creation. Figure 2B is a schematic diagram of another mechanism in the creation of the first embodiment. Figure 2C is a schematic diagram of another mechanism in the creation of the first embodiment.

10: The first solar panel

10a: Second solar panel

12: The first sprayer

20: The first lifting mechanism

30: Railcar

40: Scroll

42: Cable

50: Orbital platform

60: The second lifting mechanism

62: Sewage collection platform

70: sewage

80: Sewage discharge pipeline

90: Breeding pond

100: Mobile solar power generation mechanism

200: Sun

Claims (10)

A mobile solar power generation mechanism, including: A solar panel; A first lifting mechanism located at the bottom of the solar panel for adjusting the inclination angle of the solar panel; A rail car, installed at the bottom of the first lifting mechanism, for carrying the first lifting mechanism; A rail platform is set under the rail car to provide a moving space for the rail car; and A second lifting mechanism is arranged at the bottom of the track platform to adjust the inclination angle of the track platform. The mobile solar power generation mechanism according to claim 1, which further includes a reel, respectively located on both sides of the rail car, and connected to both sides of the rail car through a cable, and the reel is used to control the rail The speed and distance of the car moving on the track platform. The mobile solar power generation mechanism according to claim 1, wherein the rail car moves on the rail platform through an embedded wheel axle. The mobile solar power generation mechanism of claim 1, wherein the surface of the solar panel has a nano-coating to reduce the adhesion of pollutants. The mobile solar power generation mechanism according to claim 1, further comprising: a first sprayer located at one end of the solar panel for spraying and cleaning the surface of the solar panel. The mobile solar power generation mechanism according to claim 5, further comprising: a second sprayer located at the other end of the solar panel for spraying and cleaning the surface of the solar panel. The mobile solar power generation mechanism according to claim 1, wherein the first lifting mechanism and the second lifting mechanism are composed of hydraulic or pneumatic telescopic support rods. The mobile solar power generation mechanism according to claim 5, wherein the second lifting mechanism is also provided with a sewage collection platform for collecting sewage after cleaning the solar panel. The mobile solar power generation mechanism according to claim 5, which further includes: a sewage discharge pipeline located in the second lifting mechanism for discharging sewage after cleaning the solar panel. The mobile solar power generation mechanism according to claim 1, wherein the second lifting mechanism is erected above a breeding pond.

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