SU851314A1 - Test bed for facet parabolic concentrator alignment - Google Patents

Description

The invention relates to solar technology, in particular, to stands for alignment of optical elements of facet concentrators, mainly large-sized.

Bulk concentrates are typically assembled from separate units made up of facets, which are the elementary optical elements of the concentrator.

When assembling a concentrator, it is necessary to adjust the curvature of each facet, install facets in the block, adjust the curvature of each block, install the blocks on the frame of the concentrator, and adjust its curve. vienu

The alignment of each unit facet, as well as the position of the unit in the concentrator, is usually made at the stand.

A stand for alignment of the facet parabolic concentrator is known, comprising a mounting plane located tangentially to the curved surface of the facets and rotatably mounted, an artificial radiation source and a reflected beam analyzer LI-.

The installation planes are placed on the frame of the stand, which has the shape of a parabola, the source is installed in guides equidistantly spaced from the frame, can be moved along them, and the analyzer of the reflected beam is placed in the focus of the aligned concentrator.

The disadvantage of the stand is that the exact execution and positioning of the lines for the source is not necessary, which determines the accuracy of the adjustment.

A stand for adjusting the facet parabolic concentrator is known, which contains a mounting plane, which is located tangentially to the curvilinear surface, and is mounted rotatably relative to two mutually perpendicular 20 axes intersecting at the point of tangency of the plane and the facet, which reverses a flat mirror whose reflective surface is perpendicular to optical axis of the hub,

25 an artificial radiation source and an endgazher of an open beam 2.

The installation plane is placed on the frame of the stand, which has the shape of a parabola, the source is placed in the focus of the hub, and its radiation.

reflecting from an adjustable facet (or a facet block), re-reflecting a reversing plane mirror, concentrating the facet (or a facet block) and registering it with an analyzer, also located at the focus of the concentrator.

However, the necessity of positioning the installation planes along a parabola makes the stand cumbersome and complicates its design.

The purpose of the invention is to reduce the size and simplify the design of the stand.

The goal is achieved by the fact that the stand is equipped with an additional flat mirror mounted at an angle to the inverting rotatably with respect to two mutually perpendicular axes and having a center of rotation located on the straight line connecting the focus of the concentrator with the center of rotation of the installation plane, and the source and analyzer have the ability to move along a straight line parallel to the axis of the concentrator and an additional mirror passing through the center of rotation.

In addition, the additional mirror has the capability of plane-parallel movement along a straight parallel optical axis of the hub.

FIG. 1 shows a schematic diagram of a stand with one installation plane; in fig. 2 is an optical layout of the stand.

The stand for adjusting the facet parabolic concentrator (Fig. 1) contains the installation plane 1 located tangentially to the curvilinear surface of the facet 2 and installed, rotatably relative to two mutually perpendicular p of the 1st Axes intersecting at the point of tangency of the plane 1 and the facet 2, reversing the mirror. 3, the reflective surface of which is perpendicular to the optical axis of the concentrator, the source of artificial radiation 4 and the analyzer 5 of the reflected beam. The stand is equipped with an additional flat mirror b, installed at an angle to the mirror 3, rotatably with respect to two mutually perpendicular axes and having a center of rotation A located on the straight line connecting the focus of the concentrator with the center of rotation of the setup plane 1, and source 4 and analyzer 5 have the ability to move along a straight line parallel to the axis of the concentrator and rotation of the additional mirror passing through the center A b. In addition, the mirror 6 has the possibility of parallel-parallel movement along a straight line parallel to the optical axis of the concentrator.

The stand also contains readout devices 7 and 8 rotations of the installation plane 1 and mirror b, respectively, and a guiding device 9,

located perpendicular to the plane of the mirror 3 and coinciding with the line of movement of the source 4, the analyzer 5 and the mirror 6.

The installation and adjustment of the facet block on the stand is as follows.

Using the readout devices 7, a plane 1 with a facet block (in FIGS. 1 and 2, the facet block is conventionally called facet 2, the installation plane 1 tangent to the center facet of this block) is brought into design position, set at the corresponding angle of the block to the optical axis the concentrator, then S is parallel to the guide device 9 and at the same time perpendicular to the mirror 3 (Fig. 2).

The location of the mirror b (m) and the source 4c by the analyzer 5 (T.RJ) is determined by the coordinates UA and yf; , assuming that the center of the rectangular coordinate system is located at the center of rotation of the plane 1, and the axis —y is directed parallel to the optical axis of the concentrator. ...

Then the indicated coordinates are determined from the equations: YA; h ctgot; 4- si not;) -eppp, where h is the characteristic dimensions of the stand, defining the distance from the center of rotation of the setting plane 1 to the guiding device 9 |

ep, design distance from

The center of the block is a facet to the focus of the concentrator. The alignment of the blocks is done by installing a mirror in the position A corresponding to the block and parallel to plane 1 by the reading devices 8. Source 4 and analyzer 5 are also located in the corresponding position F.

The radiation of source 4 is reflected j from mirror b, falls on the facet unit (facet 2), is reflected by it and reaches the mirror 3 in a parallel beam, is addressed last, is concentrated by the facet block and reflected from the mirror b on analyzer 5. Since the setup plane 1, additional mirror b and Since the analyzer 5 is set to the design position, the adjustment reduces to adjusting the position of plane 1 to match the glare on the analyzer 5 with the point of focus of the X-ray laser.

The introduction of an additional flat mirror 6, which is installed in the design position of the adjusted block, allows you to select the characteristic stand size h on which the guide device 9 is positioned, allowing the source 4, analyzer 5 and mirror b 5 to move arbitrarily, which in turn gives

Claims (2)

Claim 1. A bench for adjusting a facet parabolic concentrator, comprising a mounting plane located tangentially to the curved facet facet and mounted to rotate relative to two mutually perpendicular axes intersecting at the point of contact of the plane and facet, facing a flat mirror whose reflective surface is perpendicular to the optical axis of the concentrator , artificial radiation source and reflected beam analyzer, characterized in that, in order to reduce the size and simplify I designs, 20 stand is equipped with an additional flat Order 6348/65 9 Signed by a mirror mounted at an angle to the rotator relative to two mutually perpendicular axes and having a center of rotation located on a straight line connecting the focus of the concentrator to the center of rotation of the installation plane, and the source and analyzer can be moved along a straight line parallel to the hub axis and passing through the center of rotation of the additional mirror. 2. The stand according to claim 1, characterized in that the additional mirror has the ability to plane-parallel movement along line ₉ parallel to the optical axis of the concentrator.