SU1260645A1 - Heat-producing unit - Google Patents

Description

The invention relates to solar technology.

A known solar plant containing a hub and a heliostat mounted pivotally in mutually perpendicular directions and having intersecting pivot axes, one of which is located along the optical axis of the concentrate, and a pivot mechanism made in the form of a drive shaft and rigid rod intersecting the optical axis of the hub connected at one end with at least one slider mounted on the heliostat, the drive shaft being installed with the possibility of synchronous rotation following the visible movement of the sun The length of the cable is equal to the distance between the point of intersection of the axis of the concentrator and the drive shaft by means of a telescopic bar fixed on them.

The disadvantage of this setup is low rigidity, which leads to a drift of the central spot relative to the geometric focus of the concentrator with sharp changes in the rotation speed of the heliostat around the axes of rotation.

The purpose of the invention is to increase the rigidity of the structure.

The goal is achieved by the fact that in a solar system containing a hub and a heliostat, installed rotatably in mutually perpendicular directions and having intersecting axes of rotation, one of which is located along the optical axis of the concentrator, the rotation mechanism, made in the form of an intersecting optical axis of the hub drive shaft and rigid cable gi, connected by one end with at least one slider mounted on the heliostat, the drive shaft being mounted with the possibility of synchronous operation rotation behind the apparent movement of the Sun, the length of the cable is equal to the distance between the point of movement of the axis of the concentrator with the drive shaft and the intersection point of the axes of the heliostat, and the tractor is connected to the drive shaft by means of a telescopic rod fixed to them, the rotation mechanism is provided with a driven shaft, installed along the optical axis of the concentrator, the rigid end of the other end is connected by means of a rotary hinge with the driven shaft, and the hinge connecting the rigid end to the rod is rotatably mounted relative to gi.

In order to improve the accuracy of tracking, the hinge connecting the rigid rod to the driven shaft is mounted for movement along the latter, and the tractor is designed for adjusting its length.

FIG. 1 shows a kinematic scheme of a solar system, an axonometric view; in fig. 2 - the same plan view; in fig. 3 shows the node I in FIG. 2

The solar station contains a hub 1 and a heliostat 2, which is mounted rotatably in mutually perpendicular directions and having intersecting axis 3 and 4 of rotation, axis 3

which is located on the optical axis 5 of the concentrator 1, and the rotation mechanism, made in the form of the concentrator 1 of the drive shaft 6 intersecting the axis 5 and the rigid rod 7 connected at one end with the sliders 8 mounted on the heliostat 2, the drive shaft being synchronously mounted rotation behind the apparent movement of the Sun, the length of t t gi 7 is equal to the distance S between the intersection point of the axis 5 of the concentrator 1 with the driving

shaft 6 and the intersection point of axes 3 and 4 of the heliostat 2, and the tractor is connected to the drive shaft 6 by means of a telescopic rod 9 hinged on them. The turning mechanism is equipped with a driven shaft 10 mounted along the optical axis 5 of the concentrator 1, rigid 7 and others the end is connected by means of a pivotal hinge 11 to the main shaft 10, and the hinge 12 connecting the rigid rod 7 to the rod 9 is mounted with the possibility

rotation relative to ti gi 7.

The hinge 11 connecting the rigid cable 7 to the driven shaft 10 is mounted for movement along the latter, and the cable 7 is configured to adjust its length by means of a telescopic connection 13.

The movement of the hinge 11 is provided by the handle 14.

Solar power plant works as follows.

At the beginning of the working day of tough 7

the daily declination of the sun is set using a telescopic rod 9, its length is changed. At the same time, hectare 7 is directed to the center of the solar disk.

The drive shaft 6 rotates at a constant angular velocity (Cii 15 degrees / h). Tg 7 performs rotational motion with the drive shaft 6 through the telescopic bar, rotating the shaft through the slider 8 and the plane of the heliostat 2 around the axis 3. The sliders 8 move along the guides.

Heliostat 2 performs a complex motion relative to the center of rotation at the intersection of axes 3 and 4, and the normal to the surface of the heliostat always remains the bisector of the acute angle formed by the optical axis 5 and the hard thrust 7.

Consequently, the reflected beam all the time remains in the plane passing through the center of the solar disk and the optical axis 5 of the hub 1 and is directed along the latter.

In those days or hours of work, when

the height of the sun is less than 30 °, the refraction has a noticeable effect on the tracking accuracy of this solar power plant.

To account for refraction, node I is provided, making it possible to make an amendment to the tracking. To do this, rotating the knob 14, move the hinge 11 by a certain amount along the optical axis 5, simultaneously adjust the length of the string 7 with the help of the telescopic joint 13 to maintain the equality 1XS, and the angle between the former position of the rigid rod 7 and the new one was equal to the maximum refraction on this day.

Thus, supplying the rotation mechanism with a driven shaft and attaching a rigid rod to it increases the rigidity of the structure, and the ability to move the rod along the driven shaft allows for a correction for refraction, which increases the tracking accuracy.

/

/ J

 -7ГГ .Z

777Iff

FIG. 3

FIG. 2

Claims (2)

1. HELIOSTATION, containing a concentrator and a heliostat mounted rotatably in mutually perpendicular directions and having intersecting rotation axes, one of which is located on the optical axis of the concentrator, and a rotation mechanism made in the form of a drive shaft intersecting the optical axis of the concentrator and rigid traction connected one end with at least one slider mounted on the heliostat, and the drive shaft is mounted with the possibility of synchronous rotation behind the visible movement of the Sun, length traction is equal to the distance between the point of intersection of the axis of the concentrator with the drive shaft and the point of intersection of the axes of the heliostat, and the rod is connected to the drive shaft by means of a telescopic rod pivotally mounted on them, characterized in that, in order to increase the rigidity of the structure, the rotation mechanism is provided with a driven shaft installed along the optical axis of the concentrator, the rigid rod at the other end is connected by means of a swivel joint to the driven shaft, and the joint connecting the rigid rod to the rod is rotatably mounted regarding the draft. 2. Solar installation according to π. 1, characterized in that, in order to increase the tracking accuracy, the hinge connecting the rigid rod to the driven shaft is installed with the possibility of movement along the latter, and the rod is made with the possibility of adjusting its length. SU, 1260645 of FIG. 7