阅读说明：本技术 一种基于日晷投影的柔性太阳能采集配重式追踪系统设计 (Design of flexible solar energy collection counterweight type tracking system based on sundial projection ) 是由 刘星宇 于 2018-12-29 设计创作，主要内容包括：本发明提供一种基于日晷投影的柔性太阳能采集配重式追踪系统设计,采用柔性太阳能采集板设计的锅状柔性太阳能采集系统,由于基板采用锅状磁性不锈钢设计,锅状磁性不锈钢采用球笼式万向节链接方式,配重磁铁吸附在锅状基板不同位置,柔性太阳能采集板的朝向会随着改变,基于日晷的投影方式,借助平行阳光对投影针的投影和光敏传感器,来标定配重磁铁吸附在锅状基板位置,从而保证锅状柔性太阳能采集系统最强照射下的工作状态。日晷的投影采用光敏传感器设计的基盘来标定配重磁铁吸附在锅状基板位置,通过无线通讯的方式发给锅状基板后的轨道配重小车,配重小车在轨道上运行到标定的锅状基板位置,配重小车在锅状基板不同位置改变锅状柔性太阳能采集系统重心,球笼式万向节链接使得柔性太阳能采集板的朝向改变到最佳工作状态。(The invention provides a design of a flexible solar energy collection counterweight type tracking system based on sundial projection, which is a pot-shaped flexible solar energy collection system designed by a flexible solar energy collection plate. The projection of the sundial adopts a base plate designed by a photosensitive sensor to calibrate a counterweight magnet to be adsorbed at the position of a pot-shaped substrate, the counterweight magnet is sent to a track counterweight trolley behind the pot-shaped substrate in a wireless communication mode, the counterweight trolley runs to the calibrated pot-shaped substrate position on a track, the counterweight trolley changes the gravity center of a pot-shaped flexible solar energy collecting system at different positions of the pot-shaped substrate, and the orientation of the flexible solar energy collecting plate is changed to the optimal working state through the ball cage type universal joint connection.)

1. The utility model provides a design of flexible solar energy collection counter weight formula tracking system based on sundial projection which characterized in that:

the utility model provides a design of counter weight formula tracker is gathered to flexible solar energy based on sundial projection, adopt the flexible solar energy collection system of pot form of flexible solar energy collection board design, because the base plate adopts the design of pot form magnetism stainless steel, pot form magnetism stainless steel adopts the rzeppa universal joint mode of linking, counter weight magnet adsorbs in the different positions of pot form base plate, the orientation of flexible solar energy collection board can be along with changing, projection mode based on sundial, with the help of projection and the photosensitive sensor of parallel sunshine to the projection needle, mark counter weight magnet and adsorb in pot form base plate position, thereby guarantee the operating condition under the strongest irradiation of the flexible solar energy collection system of pot form.

2. The method of claim 1, wherein:

a sundial is a tool for indicating time by utilizing sun projection when the sun irradiates. The shadow dial is arranged in the center of the shadow dial and is vertical to the dial surface. The sun shines on the needle, produces the projection on the quotation, and the shadow of shadow needle moves along with the motion of sun, and the position of needle shadow is different like this, can reflect the position difference of sun, and the projection of sundial adopts the basic disc of photosensitive sensor design, owing to mark counter weight magnet absorption and in pot form base plate position.

3. The method of claim 1, wherein:

the projection of the sundial adopts a base plate designed by a photosensitive sensor to calibrate a counterweight magnet to be adsorbed at the position of a pot-shaped substrate, the counterweight magnet is sent to a track counterweight trolley behind the pot-shaped substrate in a wireless communication mode, the counterweight trolley runs to the calibrated pot-shaped substrate position on a track, the counterweight trolley changes the gravity center of a pot-shaped flexible solar energy collecting system at different positions of the pot-shaped substrate, and the orientation of the flexible solar energy collecting plate is changed to the optimal working state through the ball cage type universal joint connection.

Technical Field

The invention relates to industrial control and solar energy application function research, and provides a flexible solar energy collection counterweight type tracking system design based on sundial projection by referring to an existing solar energy collection tracking device. The projection of the sundial adopts a base disc designed by a photosensitive sensor to calibrate a counterweight magnet to be adsorbed at the position of a pot-shaped substrate, and sends the counterweight magnet to a track counterweight trolley behind the pot-shaped substrate in a wireless communication mode, the counterweight trolley runs to the calibrated pot-shaped substrate position on a track, the counterweight trolley changes the gravity center of a pot-shaped flexible solar energy collecting system at different positions of the pot-shaped substrate, and the ball cage type universal joint is connected to change the orientation of the flexible solar energy collecting plate to the optimal working state, so that the calculation speed and the adjustment precision are improved, and the maintenance and use cost is reduced.

Background

The solar automatic tracking device is used for tracking the sun, so that the main optical axis of the energy collector is always parallel to the sun ray. To achieve this, in use, the sun needs to be continuously tracked in both azimuth and elevation angles, so that the concentrator is always aligned with the sun from sunrise to sunset, thereby improving the utilization rate of solar energy. In the aspect of solar tracking, a single-shaft solar tracker is developed in 1997 by biacca in the united states, so that the automatic tracking in the east-west direction is completed, and the thermal yield of a receiver is improved by 15% through manual adjustment in the north-south direction. In 1998, the two-axis tracker of ATM was successfully studied in California of Guangdong, and the solar panel was equipped with a Fresnel lens for concentrating sunlight, so that the small solar panel silicon can collect more energy, and the heat transfer rate can be further improved. A novel solar tracking device is provided by the university of Arizona in America in 2 months in 2002, the device completes tracking by using a control motor, adopts an aluminum profile frame structure, is compact in structure and light in weight, and greatly widens the application field of a tracker. In recent years, a plurality of experts and scholars in China have also successively developed the research on the aspect, an automatic solar cooker tracking system is proposed in 1992, and a single-shaft hydraulic automatic tracker introduced in solar journal in 1994 completes one-way tracking.

There are many ways to track the sun, but not exclusively, these two ways: photoelectric tracking and tracking according to the sight day motion trail. The latter tracking method can be divided into two-axis tracking and single-axis tracking.

At present, a universal solar tracking system in the world needs to calculate the angle of the sun at different moments of each day in a year according to information such as longitude and latitude of a placement point, store the position of the sun at each moment in the year into a PLC (programmable logic controller), a singlechip or computer software, and realize tracking by calculating the position of the sun at each moment of a fixed place. The computer data theory is adopted, data and setting of latitude and longitude regions of the earth are needed, once the device is installed, the device is inconvenient to move or assemble and disassemble, and parameters must be recalculated, data is set and each parameter must be adjusted after the device is moved every time.

The following three tracking methods are generally adopted for single-axis tracking: arranging the object tracking obliquely; the focal lines are horizontally arranged in south and north, and east and west tracking is carried out; the focal lines are arranged horizontally and tracked north and south. The three modes are basically the north-south direction or east-west direction tracking of single-axis rotation, and the working principle is basically similar. Taking the third tracking mode as an example, the principle of single-axis tracking is explained. Fig. 1 is a principle of this tracking manner. The axis of rotation (or focal line) of the tracking system is arranged in the east-west direction. Then the cylindrical paraboloidal reflector rotates around the rotating shaft in a pitching mode according to the change of the declination angle of the sun so as to track the sun. When the tracking mode is adopted, only the solar light at noon is vertical to the generatrix of the cylindrical paraboloid in one day, and the heat flow is maximum at the moment. In the morning or afternoon, the sunlight is obliquely emitted, so the heat flow changes greatly in one day. The single-axis tracking method has the characteristic of simple structure, but is not ideal for collecting solar energy because the incident light cannot be parallel to the main optical axis all the time. The maximum solar energy can be obtained if the sun can be tracked both in the variation of the solar altitude and declination angle, and the full tracking, i.e. the two axes, is designed according to the requirement.

The dual-axis tracking can be divided into two modes, namely polar axis type full tracking and altitude angle-azimuth angle type full tracking. The polar axis type full tracking principle is shown in fig. 2. One axis of the condenser is directed to the north pole of the celestial sphere, i.e., parallel to the axis of rotation of the earth, and is called the polar axis. The other axis is perpendicular to the polar axis and is called declination axis. When the reflector works, the reflector only needs to use a fixed rotating speed which is opposite to the direction of the rotation angular speed of the earth around the polar axis so as to track the sun looking movement. In addition, the reflector is intermittently rotated around the declination axis in a pitching mode according to the change of seasons so as to adapt to the change of the declination angle. This tracking is not complicated, except that the weight of the mirror does not pass through the axis of the polar axis, making the design of the polar axis bearing difficult.

The design of the two-axis photoelectric automatic tracking system for the solar panel is shown in figure 3. The detection of the measuring device gives azimuth signals of the sun in the east-west direction and the south-north direction. Then, after the signal is compared with the attitude signal of the solar panel in the PLC system, a motor action signal is output so that the motor in the east-west direction rotates to adjust the attitude of the solar panel in the east-west direction, and meanwhile, the motor in the north-south direction also rotates to adjust the attitude of the solar panel in the north-south direction, and finally the purpose that the solar panel is vertical to sunlight is achieved. Both the photoelectric tracking method and the tracking method based on the sight day movement locus have the problems of relatively complex movement control and higher maintenance and use cost.

Disclosure of Invention

Due to the rotation of the earth, compared with a solar photovoltaic power generation system at a fixed place, the solar photovoltaic power generation system can change the illumination angle of the sun all the time and at any moment in four seasons and every day in spring, summer, autumn and winter every year, so that the solar panel can be effectively ensured to be over against the sun all the time, and the power generation efficiency can reach the optimal state. The invention aims to provide a pot-shaped flexible solar energy collection counterweight type tracking system design based on sundial projection, which is applied to the solar energy industry and improves the utilization rate of solar energy.

According to the sundial sun projection indication principle, a sundial is installed in the center of the sundial and is perpendicular to the dial surface, the sun shines on the sundial to generate projection on the dial surface, the shadow of the sundial moves along with the movement of the sun, so that the positions of the shadow of the sun can be reflected to be different, the projection of the sundial adopts a base plate designed by a photosensitive sensor, the base plate designed by the sundial sun projection photosensitive sensor calibrates the counter weight magnet to be adsorbed on the pot-shaped base plate, and the base plate calibrates the counter weight magnet to be adsorbed on the pot-shaped base plate.

The projection calibration counterweight magnet of the sundial is adsorbed at the position of the pot-shaped base plate and is sent to the track counterweight trolley behind the pot-shaped base plate in a wireless communication mode, the counterweight trolley runs to the position of the calibrated pot-shaped base plate on the track, the counterweight trolley changes the gravity center of the pot-shaped flexible solar energy collection system at different positions of the pot-shaped base plate, and the orientation of the flexible solar energy collection plate is changed to the optimal working state through the ball cage type universal joint connection. Hardware block diagram of flexible solar energy collection counterweight type tracking system based on sundial projection is shown in fig. 5

The invention aims to provide a flexible solar energy collection counterweight type tracking system based on sundial projection, which is light and handy in structure, convenient to install and maintain, and capable of improving the calculation speed and the adjustment precision.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this application, illustrate embodiment(s) of the invention and together with the description serve to explain the principles of the invention. In the drawings:

FIG. 1 shows a focal line east-west horizontal arrangement of north-south tracking;

FIG. 2 is a polar tracking;

FIG. 3 is a two-axis photoelectric automatic tracking system for a solar panel;

FIG. 4 is a control process of a flexible solar energy collection counterweight type tracking system based on sundial projection;

FIG. 5 is a hardware block diagram of a flexible solar energy collection counterweight type tracking system based on sundial projection;

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention will be described in further detail with reference to the following embodiments and accompanying drawings. The exemplary embodiments and descriptions of the present invention are provided to explain the present invention, but not to limit the present invention.

The embodiment provides a processor circuit designed based on an M430 general processing chip of TI company and an EPM3128ATI64 programmable device based on Altra company, and realizes the calibration of photoelectric positions and the movement of a counterweight trolley by combining a power supply circuit, an input photoelectric acquisition circuit, a processor, a storage circuit, an analog quantity acquisition circuit, a digital quantity acquisition circuit, a driving circuit and a bus circuit.

Adopt flexible solar energy collection system of pot form of flexible solar energy collection board design, because the base plate adopts the design of pot form magnetism stainless steel, pot form magnetism stainless steel adopts the rzeppa universal joint mode of linking, counter weight magnet adsorbs in the different positions of pot form base plate, the orientation of flexible solar energy collection board can be along with changing, based on the projection mode of sundial, with the help of projection and the photosensitive sensor of parallel sunshine to the projection needle, mark counter weight magnet and adsorb in pot form base plate position, thereby guarantee the operating condition under the strongest irradiation of pot form flexible solar energy collection system.

The above-mentioned embodiments are intended to illustrate the objects, technical solutions and advantages of the present invention in further detail, and it should be understood that the above-mentioned embodiments are merely exemplary embodiments of the present invention, and are not intended to limit the scope of the present invention, and any modifications, equivalent substitutions, improvements and the like made within the spirit and principle of the present invention should be included in the scope of the present invention.