SU1097563A1 - Concentrator of light radiation and method for making hologram therefor - Google Patents

Abstract

1. A hub of light in the form of a prism, containing faces of the entrance, reflection and exit of radiation. The difference is that, in order to increase the degree of concentration, the edge of the entrance of radiation has a photosensitive layer with a volume hologram. (L s ± s JV O 00

Description

2. A method of manufacturing a hologram for a hub according to claim 1 by recording the interference pattern on the photosensitive layer from the plane-parallel reference and plane-parallel subject laser beams, the latter being introduced through an optical element and an immersion liquid layer, characterized in that application, the optical element is installed from the side of the photosensitive layer and the Object beam is introduced into the prism parallel to the face of reflection of the radiation.

3. The method according to claim 2 is also distinguished by the fact that, in order to expand the working range of the concentrator being manufactured, a second optical element is installed from the side of the reflection face through the layer of immersion liquid, the subject beam is inserted into the photosensitive

layer at an angle greater than the angle of total internal reflection, on the boundary of the photosensitive layer and air, and the reference beam is normal to the edge of the radiation input successively through each; optical element ±.

4. A pop-up method, characterized in that, in order to increase the degree of contcentration, the object beam is inserted into a prism, and in the rt section of the trapezoid, at an angle to the reflection face, greater than the total internal reflection angle, at the interface of the prism and air, which is determined by the formula

yiQ + 2 ", n.

de Q is the angle of complete internal combustion at the interface between prism and air; A is the angle between the faces of the entrance and

prism reflection; and is the maximum number of reflections of a beam of concentrated radiation inside ...

The invention relates to solar technology, in particular, to hubs of light radiation in the form of prisms, and methods for producing a hologram for hubs.

A hub of light is known in the form of a prz-i, containing the faces of the entrance, reflection and output of radiation l.

In this method, the concentration is realized due to multiple total internal reflections of the radiation. Here, the concentration coefficient is determined by the magnitude of the total internal reflection angle associated with the optical density of the material from which the prism is made. An increase in the concentration ratio can be achieved by applying a specular coating on the reflection face. However, in this case, the concentration ratio is limited by the optical density of the prism material.

The known method of making a hologram is by recording an interLetration pattern on a photosensitive layer from a plane-parallel reference and plane-parallel subject laser beam, the latter being introduced through an optical element and a layer of immersion liquid 2.

When the reference beam is directed from the side of the photosensitive layer, and on the opposite side

the plates apply a layer of immersion liquid and place a prism on it and direct a beam of radiation through it.

When the subject beam reaches the border of the photosensitive air layer, total internal reflection occurs. When the reference beam is interlevered with a falling object beam, a reflection hologram is formed, and if the reference beam interferes with the reflected object beam, a transmission hologram is also formed at the same time.

However, a plate with such holograms cannot concentrate radiation, since when directed to

a beam of light identical to the reference beam, a part of the beam does not penetrate into the plate, reflected on the reflection hologram, and a part of the beam diffracted by

the hologram, undergoes total internal reflection on the opposite side of the plate, becomes identical to the subject beam and exits the plate.

In addition, the subject beam cannot be concentrated, since it cannot be inserted into the plate at an angle of total internal reflection without a prism with an immersion liquid. Even with a prism, he, by diffraction, reconstructs the reference beam of radiation and exits the plate, and the undifferentiated part of it is fully reflected at the interface of the photosensitive layer - air and exits the plate through the immersion layer and the prism. The purpose of the invention is to increase the degree of concentration of a recognized concentrator and expand the scope of the method of making a hologram for use in a recognized concentrator, expanding the operating range of the concentrator produced and further increasing its degree of concentration. The goal is achieved by the fact that the edge of the radiation input has a photosensitive layer with a volume hologram, the optical element is mounted on the side of the photosensitive layer, and the object beam is inserted into the prism parallel to the edge of reflection of the radiation. In addition, a second optical element is installed on the side of the reflection face through the layer of immersion liquid, the object beam is inserted into the photosensitive layer at an angle greater than the angle of total internal reflection, at the interface of the photosensitive layer and air, and the reference beam is normal to the edge of radiation input successively through each optical element, and the object beam is introduced into the prism, having a cross section of the shape of a trapezoid, at an angle f to the reflection face, the larger angle of total internal reflection, at the interface and the prism and the air, which is determined by Laure mule. the angle of total internal reflection at the interface of the prism and air; the angle between the entrance and reflection edges of a prism, the maximum number of reflections of a beam of a beam of concentrated radiation inside at. Fig. 1 shows a prism in the form of a prism and a method for producing a log for it, which provides a high degree of concentration of radiation in a narrow region of the spectrum; Fig. 2 shows a concentrator in the form of a prism having a trapezium lormu in cross section, and a method for producing i holo MF / tJ for it, which provides either a wide spectrum of concentrated radiation or an increase in concentration in a narrower spectrum. A hub of light in the form of prisms 1 ((gg.1) contains the face 2 of the radiation input, the face 3 of the reflection of radiation and the face 4 of the radiation output. The face 2 of the radiation input has a photosensitive 5 with a volume hologram. recording the interference pattern on the photosensitive layer 5 (Fig. 1) from a plane-parallel reference beam 6 and a plane-parallel subject laser beam 7, which is introduced through the optical element 8 and 9 of the immersion liquid. The cue element 8 is installed on the side of the photosensitive layer 5, and the object beam 7 is inserted into the prism 1 parallel to the radiation reflection face 3. To expand the spectrum of the concentrated radiation, from the side of face 3 (Fig. 2), a second the optical element 11, the subject beam 12 is introduced into the photosensitive layer 5 at an angle greater than the angle of total internal reflection at the interface of the photosensitive layer 5 and air, and the reference beam 13 is introduced normally to the edge 2 of the entrance students successively through each optical element 8 and 11. To further increase the degree of concentration in a fairly wide spectral region (compared to the previous version, the spectrum of the concentrated radiation is narrowed), the object beam 14 is inserted into the prism 15 (Fig. 2), having a cross section a trapezoid, at an angle to the face 3 of the reflection, greater than the angle of total internal reflection, at the interface of the prism 15 and air, which is determined by the formula for iQ -2cin. The method of making a hologram for a hub and its operation is carried out in the following way. In the case of making a hologram for a high concentration of radiation prism in a narrow region of the spectrum, the object beam 7 (Fig. 1) is introduced into the prism 1 through the optical element 8, made in the form of a straight prism, and the layer 9 of the immersion liquid applied to the light-sensitive layer 5, in turn, located on face 2 of the radiation input. Prism 1 has a rectangular triangle in cross section, and beam 7 is parallel to face 3 of the reflection. The reference beam 6 is introduced into the prism 1 through the optical element 8 and the layer 9 of the imglersional fluid, but perpendicular to the face 2 of the radiation input and the surface of the photosensitive layer 5. The volume hologram can be of either a transmission or a traction type. Concentrated light radiation, after a single dilraction on a volume hologram, leaves the verge 4 of a prism without any reflections. Therefore, the angle between the two side faces 2 and 3 of pris-rz 1 does not depend on the CBqficTB volume hologram. This ANGLE determines the angle between the reference beam b and the subject beam 7 during the formation of the hologram and, therefore, the spectral sensitivity of the volume hologram. In the manufacture of holograms for concentration of radiation, a prism concentrator in a wide spectral region, on both faces 2 and 3 of the prism 15 (Fig. 2), layers 9 and 10 of immersion liquid are applied and optical elements 8 and 11 are installed, made in the form of direct prisms . The object beam 12 is guided through the optical element 8 and the layer 9 of the immersion liquid so that inside the light of the sensitive layer 5 the angle between the direction of propagation of the beam 12 and the normal to the interface of the photosensitive layer 5 and the layer of immersion liquid is greater than the angle of total internal reflection at the boundary section of the photosensitive layer 5 and air. In order to form a scientific research institute of a transmissive volume hologram, the reference beam 13 directs the optical element 8 and the layer 9 of immersion liquid, preferably perpendicular to the surface of the layer 5 and the face 2 of the radiation input. When a reflective volume hologram is formed, the reference beam 13 is guided through the optical element 11 and the layer 10 of the immersion liquid perpendicular to the face 2 of the radiation input. Compared to a transmissive volume hologram, a reflective volume hologram has a higher selectivity to wavelength and a smaller selectivity to the angle of incidence of the restoring beam. The object beam 12 is inserted into the prism 15 at an angle of total internal reflection due to the fact that layers 9 and 10 of immersion liquid are applied on both surfaces of its side faces 2 and 3 and an auxiliary prism is installed (optical elements 8 and 11). The reference beam 13 and the subject beam 12 thus form only a transmissive volume hologram, when interfering waves fall on one side of the photosensitive layer 5, and the reflective one - on opposite sides. The volume hologram is a volume diffraction grating containing periodically dispersed scattering planes, which halves the angle between the directions of propagation of the reference beam and the object beam in a photosensitive medium. Here, the angle between the propagation spread of the beam and the scattering plane is the Bragg angle. If the reference beam falls on such a hologram at the Bragg angle, then it degrades on the scattering planes in the direction of the object beam, since it is in this direction that the in-phase addition of the light waves scattered by the planes occurs and the intensity of the diffracted wave has the maximum value. Similarly, a subject beam falling on a hologram at a Bragg angle restores the reference beam. When the angle of incidence of the beam deviates from the Bragg angle, the intensity of the diffracted wave decreases. Thus, for example, for a Bragg angle about about 15 μm thick inside the gelatinous photosensitive layer, with an angular deviation of less than 2 °, the diffraction efficiency of the volume transmissive hologram drops to zero. In particular, the limiting angular deviation. (3 radians) for the volume transmissive hologram is approximately defined as the ratio of the distance between the interference scattering planes to the thickness of the photosensitive layer. When a hub with such a hologram is illuminated with a beam identical to the reference beam 13, in the photosensitive layer 5 the restored object beam 12 propagates at an angle of total internal reflection. Thus, the beam is introduced from the optically less dense medium of air) B optically more dense medium (photosensitive layer 5 and prism material 15), at the angle of total internal reflection without using an auxiliary prism and immersion liquid. The beam that entered the prism 113 is reflected from the opposite side face 3 of the prism 15 and hits the volume hologram recorded in the photosensitive layer 5. It is necessary that this beam, after reflection at the interface of the photosensitive layer 5 and air, falls on the scattering plane a diffraction grating with an angular deviation from the Bragg angle not less than the angular deviation at which the diffraction efficiency of the volume hologram is zero. In that

Claims (4)

1. The concentrator of light radiation in the form of a prism containing the edges of the input, reflection and output of radiation, characterized in that, in order to increase the degree of concentration, the face of the radiation input has a photosensitive layer with a volume hologram. 2. A method of manufacturing a hologram for a concentrator according to claim 1 by recording an interference pattern on a photosensitive layer from a plane-parallel reference and plane-parallel. a single object laser beam, the latter being introduced through the optical element and the immersion liquid layer, characterized in that, in order to expand the scope, the optical element is mounted on the side of the photosensitive layer and the object beam is introduced into the prism parallel to the radiation reflection face. '' 3. The method 'according to claim 2, characterized in that, in order to expand the operating range of the manufactured concentrator, from the side of the reflection side, a second optical element is installed through the immersion liquid layer, the object beam is introduced into the photosensitive layer at an angle greater than the angle of the full internal reflection, on the border! photosensitive layer and air, and the reference beam is normal to the edge of the radiation input sequentially through each optical element. 4. The method according to p. 3, characterized in that, in order to increase the degree of concentration, the object beam is introduced into a prism having a trapezoidal cross section, at an angle β to the reflection face, greater than the angle of total internal reflection, at the interface of the prism and air, which is determined by the formula for i Q + 2 l η. Food Q. Is the angle of total internal reflection at the interface between the prism and air, ' Λ is the angle between the faces of the entrance and reflection of the prism; η is the maximum number of reflections of the beam of concentrated radiation inside the prism.