FR3035228A1 - OPTICAL SYSTEM - Google Patents

Abstract

The general principle of the invention is based on an optical system (100) of transparent material for wavelengths included in a set of beams of light ray (141-143) and for aligning the set of beams of light rays by to a main optical axis (O ') from a light source (120) to obtain a sharp image.

Description

FIELD OF THE DISCLOSURE The field of the present invention is that of lighting devices. It particularly, but not exclusively, concerns the field of optical systems for projectors, for example for projectors used for shows, in particular for lighting a stage. More specifically, the present invention relates to aplanar optical systems for aligning a set of light beams with respect to a main optical axis from a light source. PRIOR ART Nowadays, the stage or show spotlights consist of a light source constituted for example by a bulb, a discharge or incandescent lamp or by monochromatic or white electroluminescent diodes in order to obtain a color. or a range of colors. The projectors are provided, for this purpose, with a reflector (parabolic or elliptical) to collimate the light beam from this light source to a projection system, for example a zoom, comprising one or more optical systems arranged on the way of the light beam and in front of which can be placed different shutters or covers for the realization of special effects (color wheel, iris and / or Gobos for example).

In practice, it is found that the peripheral part operating in reflection of a conventional collimator used in the stage projectors does not form the image, even fuzzy, of the light source placed at the object focus. Instead of this image of the light source, there is an irregular representation that can present a symmetry of revolution. This disadvantage is very troublesome when in certain applications, it is sought a luminous flux or more precisely the transport of a luminous flux having a geometric extent as low as possible, as in the case of light boxes for example. This phenomenon is acceptable in lighting applications where imaging phenomena are undesirable. On the other hand, in luminous flux transport applications where it is desired to alter the geometric extent as little as possible, it is necessary to use planar systems. This excludes a priori conventional collimators such as those shown later in the present description. There is therefore a need for an optical system to provide a sharp image of the light source with the smallest possible geometric extent and to capture all the light emitted by the light source using a single component . SUMMARY OF THE INVENTION The object of the present invention is to solve all or some of the disadvantages mentioned above in the form of an optical system made of transparent material for wavelengths included in a set of beams of light rays and for aligning said set of light beams with respect to a main optical axis from a light source, said light source comprising a transmission center located on the main optical axis and at least one radiation emitting surface lights intended to be diffused in a space of refractive index greater than or equal to one; said optical system comprising: a cavity; the cavity being configured to receive said light source through an opening allowing access to the cavity at a positioning location for receiving all or part of the light source and comprising a first surface incident device configured to refract the light rays from the light source to a first emergent surface and a second incident surface extending on the periphery of the positioning location between a first edge and a second edge adjacent to the first incident surface and configured to refract light rays from the light source to the second emergent surface; and a side surface; the lateral surface defining an outer wall extending between the first edge of the second incident surface and the second emergent surface; the lateral surface being configured to reflect by total internal reflection light rays from the second incident surface to an intermediate focus zone of the second emergent surface 3035228 3 disposed between the side surface and the second incident surface; characterized in that: the second incident surface and the lateral surface are configured to define an intermediate focus area disposed between the lateral surface and the second incident surface, the intermediate focus area representing a focus area of the second surface emerging. Thanks to the arrangements according to the invention, the optical system makes it possible to align the set of beams of light rays with respect to the main optical axis from the light source. According to one embodiment, the optical system is configured such that light rays from the light source whose emission angle is close to the maximum aperture angle of the light source emerge from the second surface. emerging near the peripheral end of the optical system and the light rays from the light source whose emission angle is furthest from the maximum aperture angle emerging from the second emergent surface near the main optical axis. In other words, the optical system is configured such that the higher the angle of emission of a light beam from the light source is away from the maximum aperture angle of the light source, the more the respective emergent light beam is close to the main optical axis. In contrast, the optical system is configured such that the higher the angle of emission of a light beam from the light source is close to the maximum aperture angle of the light source, the larger the beam radius. respective emergent light is distant from the main optical axis. In other words, the optical system is configured so that the distance of an emergent light ray with respect to the main optical axis increases as a function of the increase in the emission angle of the respective light beam from of the light source, and reciprocally the distance of an emerging light beam with respect to the main optical axis decreases as a function of the decrease in the emission angle of the respective light beam from the light source. Thanks to the arrangements according to the invention, the optical system makes it possible to invert the light rays in order to obtain a planar system. By opening angle is meant the opening angle between the light beam and the main optical axis and maximum aperture angle, the light rays emitted by the light source with a maximum opening angle. According to one embodiment, the second incident surface and the lateral surface comprise an image focus area.

According to one embodiment, the second emergent surface comprises an object focus zone. According to one embodiment, the focus zone comprises an object focus zone. According to one embodiment, the image focus zone is merged with the intermediate focus zone. According to one embodiment, the object focus zone is merged with the intermediate focus zone. According to one embodiment, the first incident surface is defined by a first incident optical element and the first emergent surface is defined by a first emergent optical element, the first incident optical element and the first emerging optical element forming a biconvex aspheric optical element. . According to one embodiment, the lateral surface is configured to reflect, by total internal reflection, the light rays coming from the second surface incident towards the second emergent surface so that the light rays emerging from the second emergent surface are included in an angle between 0 ° and 10 °, in particular between 0 ° and 5 ° and preferably between 0 ° and 3 ° relative to the main optical axis and the light ray emerging from the first emergent surface. According to one embodiment, the second emergent surface is disposed laterally with respect to the first emergent surface.

According to one embodiment, the first emergent surface and the second emergent surface comprise a common delimitation. According to one embodiment, the first emergent surface defines a first emergent optical element.

Thus, thanks to this arrangement, the light rays coming from the first incident surface are guided by refraction. According to one embodiment, the second emergent surface is disposed laterally with respect to the first emergent surface. According to one embodiment, the first emergent surface and the second emergent surface 10 comprise a common delimitation. In particular, the second emergent surface delimits the lateral edge of the first emergent surface. Thus, thanks to these arrangements, the size of the optical system is reduced. According to one embodiment, the second emergent surface defines a second emerging optical element. Thus, thanks to this arrangement, the light rays coming from the second incident surface are guided by refraction. According to one embodiment, the optical system further comprises a peripheral seat.

Thus, thanks to this arrangement, the optical system can be installed. According to one embodiment, the peripheral seat comprises a laying plane. Thus, thanks to this arrangement, the peripheral seat can be arranged on the laying plane.

According to one embodiment, the peripheral seat further comprises an opening comprised in the laying plane. Thus, thanks to this arrangement, the light source can be placed in the cavity at the opening.

According to one embodiment, the first incident surface is defined by a first incident optical element. According to one embodiment, the first incident optical element and the first emerging optical element form a plano-convex optical element.

According to one embodiment, the first incident optical element and the first emerging optical element form a biconvex aspheric optical element. Thus, thanks to this arrangement, the optical system can be aplanatic for the light rays incident to the first incident surface.

According to one embodiment, the second incident surface is defined by a second incident optical element. According to one embodiment, the first incident optical element and the second incident optical element totally or partially form the cavity. Thus, thanks to this arrangement, when the light source is introduced into the cavity, the light source is opposite the incident optical elements. According to one embodiment, the first incident surface and the second incident surface comprise an intersection zone. Thus, thanks to this arrangement, the intersection zone delimits the first incident surface of the second incident surface. According to one embodiment, the first incident surface and the second incident surface comprise a first singular point. Thus, thanks to this arrangement, the first singular point delimits the first incident surface of the second incident surface.

According to one embodiment, the first incident surface and the second incident surface comprise a first common singular point. Thus, thanks to this arrangement, the first common singular point delimits the first incident surface of the second incident surface.

According to one embodiment, the first incident surface and the second incident surface comprise a first singular line. Thus, thanks to this arrangement, the first singular line delimits the first incident surface of the second incident surface.

According to one embodiment, the first incident surface and the second incident surface comprise a first common singular line. Thus, thanks to this arrangement, the first common singular line delimits the first incident surface of the second incident surface. According to one embodiment, the first incident surface and the second incident surface comprise a first cusp. Thus, thanks to this arrangement, the first cusp point delimits the first incident surface of the second incident surface. According to one embodiment, the first incident surface and the second incident surface comprise a first cusp.

Thus, thanks to this arrangement, the first cusp line delimits the first incident surface of the second incident surface. According to one embodiment, the intersection zone is a first singular point. Thus, thanks to this arrangement, the first singular point makes it possible to delimit the first incident surface of the second incident surface. According to one embodiment, the intersection zone is a first common singular point. Thus, thanks to this arrangement, the first common singular point delimits the first incident surface of the second incident surface.

According to one embodiment, the intersection zone is a first singular line.

Thus, thanks to this arrangement, the first singular line delimits the first incident surface of the second incident surface. According to one embodiment, the intersection zone is a first common singular line.

Thus, thanks to this arrangement, the first common singular line delimits the first incident surface of the second incident surface. According to one embodiment, the first singular point is a first cusp. Thus, thanks to this arrangement, the first cusp 10 delimits the first incident surface of the second incident surface. According to one embodiment, the first common singular point is a first cusp. Thus, thanks to this arrangement, the first cusp point delimits the first incident surface of the second incident surface.

According to one embodiment, the first singular line is a first cusp line. Thus, thanks to this arrangement, the first cusp point delimits the first incident surface of the second incident surface. According to one embodiment, the first common singular line is a first cusp line. Thus, thanks to this arrangement, the first cusp line delimits the first incident surface of the second incident surface. According to one embodiment, the first emergent surface and the second emergent surface are integral with the main body.

Thus, thanks to this arrangement, the loss of light is minimized between the first emergent surface and the second emergent surface.

According to one embodiment, the first optical element emerges and the second emerging optical element are integral with the main body. Thus, thanks to this arrangement, the loss of light is minimized between the emerging optical elements and the main body.

According to one embodiment, the first emergent surface and the second emergent surface comprise a second singular point. Thus, thanks to this arrangement, the second singular point delimits the first emergent surface of the second emergent surface. According to one embodiment, the first emergent surface and the second emergent surface comprise a second common singular point. Thus, thanks to this arrangement, the second common singular point delimits the first emergent surface of the second emergent surface. According to one embodiment, the first emergent surface and the second emergent surface comprise a second singular line. Thus, thanks to this arrangement, the second singular line delimits the first emergent surface of the second emergent surface. According to one embodiment, the first emergent surface and the second emergent surface comprise a second common singular line.

Thus, thanks to this arrangement, the second common singular line delimits the first emergent surface of the second emergent surface. According to one embodiment, the first emergent surface and the second emergent surface comprise a second cusp point.

Thus, thanks to this arrangement, the second cusp point makes it possible to define the first emergent surface of the second emergent surface.

According to one embodiment, the first emergent surface and the second emergent surface comprise a second cusp line. Thus, thanks to this arrangement, the second cusp line delimits the first emergent surface of the second emergent surface 5. According to one embodiment, the intersection zone is a second singular point. Thus, thanks to this arrangement, the second singular point makes it possible to distinguish the first emergent surface from the second emergent surface.

According to one embodiment, the intersection zone is a second common singular point. Thus, thanks to this arrangement, the second common singular point makes it possible to distinguish the first emergent surface from the second emergent surface.

According to one embodiment, the second singular point is a second cusp point. Thus, thanks to this arrangement, the second cusp point delimits the first emerging surface of the second emergent surface.

According to one embodiment, the second singular line is a second cusp line. Thus, thanks to this arrangement, the second cusp line delimits the first emergent surface of the second emergent surface.

According to one embodiment, the main body is integral with the first incident optical element. Thus, thanks to this arrangement, the loss of light is minimized between the first incident optical element and the main body.

According to one embodiment, the main body is integral with the second incident optical element. Thus, thanks to this arrangement, the loss of light is minimized between the second incident optical element and the main body.

According to one embodiment, the first emergent surface is close to the second emergent surface. Thus, thanks to this arrangement, the loss of light is minimized between the first emergent surface and the second emergent surface. According to one embodiment, the first emergent surface is adjacent to the second emergent surface. Thus, thanks to this arrangement, the loss of light is minimized between the first emergent surface and the second emergent surface. According to one embodiment, the first emergent surface comprises a first emergent optical element.

Thus, thanks to this arrangement, the first emergent surface can modify the trajectory of the light rays. According to one embodiment, the second emergent surface comprises a second emerging optical element. Thus, thanks to this arrangement, the second emergent surface can modify the trajectory of the light rays. According to one embodiment, the second emergent element is disposed laterally with respect to the first emergent optical element. According to one embodiment, the first optical element emerges and the second emergent element comprise a common delimitation. In particular, the second emergent element delimits the lateral edge of the first emergent optical element. Thus, thanks to these arrangements, the size of the optical system is reduced.

Thus, thanks to this arrangement, all the light rays emitted at the periphery of the light source can be directed substantially in the direction of the optical axis. According to one embodiment, the end of the second emerging surface is adjacent to the end of the first emergent surface. Thus, thanks to this arrangement, the loss of light is minimized between the first emergent surface and the second emergent surface. According to one embodiment, the optical system further comprises an axial symmetry with respect to the main optical axis.

Thus, thanks to this arrangement, all emerging light rays are substantially symmetrical with respect to the main optical axis. According to one embodiment, the second emergent surface comprises a secondary optical axis. Thus, thanks to this arrangement, all the light rays emitted at the periphery of the light source can be directed substantially with respect to the secondary optical axis. According to one embodiment, the second emerging optical element comprises a secondary optical axis. Thus, thanks to this arrangement, all the light rays emitted at the periphery of the light source can be directed substantially with respect to the secondary optical axis. According to one embodiment, the secondary optical axis comprises an angle between 0 ° and 10 °, in particular between 0 ° and 5 ° and preferably between 0 ° and 3 ° relative to the main optical axis.

Thus, thanks to this arrangement, all the light rays emitted can be directed with respect to the main and secondary optical axis. According to one embodiment, the optical system further comprises a planar symmetry with respect to the main optical axis.

Thus, thanks to this arrangement, all emerging light rays are substantially symmetrical with respect to the main optical axis. According to one embodiment, the planar symmetry of the optical system is included in a plane passing through the main optical axis and the secondary optical axis. Thus, thanks to this arrangement, the set of emerging light rays is substantially symmetrical with respect to the main optical axis. According to one embodiment, the main optical axis is included in the plane of symmetry of the optical system.

Thus, thanks to this arrangement, all emerging light rays are substantially symmetrical with respect to the main optical axis. According to one embodiment, the secondary optical axis is included in the plane of symmetry of the optical system. Thus, thanks to this arrangement, the set of emerging light rays 15 is substantially symmetrical with respect to the main optical axis. According to one embodiment, the optical system further comprises a symmetry of revolution with respect to the main optical axis. Thus, thanks to this arrangement, the set of emerging light rays is substantially symmetrical with respect to the main optical axis.

According to one embodiment, the first incident surface is configured to refract the light rays from the light source towards the first emergent surface so that the light rays emerging from the first emergent surface are included in an angle between 0 ° and 10 °, in particular between 0 ° and 5 ° and preferably between 0 ° and 3 ° with respect to the main optical axis. Thus, thanks to this arrangement, the set of emerging light rays is substantially parallel to the main optical axis. According to one embodiment, the lateral surface is configured to reflect, by total internal reflection, the light rays coming from the second surface incident towards the second emergent surface so that the light rays emerging from the second emergent surface are included in an angle between 0 ° and 10 °, in particular between 0 ° and 5 ° and preferably between 0 ° and 3 ° with respect to the main optical axis and the light ray emerging from the first emergent surface.

Thus, thanks to this arrangement, all emerging light rays are substantially parallel to the main optical axis. In parallel, generally means an angle between 0 ° and 10 °, in particular between 0 ° and 5 ° and preferably between 0 ° and 3 ° relative to a reference. According to one embodiment, the first emergent surface comprises a convex shape. Thus, thanks to this arrangement, the first emergent surface makes it possible to form a convergent surface. According to one embodiment, the second emergent surface has a convex shape.

Thus, thanks to this arrangement, the second emergent surface makes it possible to form a convergent surface. According to one embodiment, the first incident surface comprises a convex shape. Thus, thanks to this arrangement, the first incident surface makes it possible to form a convergent surface. According to one embodiment, the second incident surface has a convex shape. Thus, thanks to this arrangement, the second incident surface makes it possible to form a convergent surface.

According to one embodiment, the assembly formed of the first incident surface and the first emergent surface comprises an object focus situated in the vicinity of the light source 30. Thus, thanks to this arrangement, the assembly formed of the first surface incident and the first emergent surface allows to focus the light rays. According to one embodiment, the second emergent surface comprises an intermediate focus area located within the optical system. Thus, thanks to this arrangement, the intermediate focus zone allows the optical system to converge the light rays. According to one embodiment, the intermediate focus zone comprises a planar symmetry with respect to the main optical axis.

Thus, thanks to this arrangement, all emerging light rays are substantially symmetrical with respect to the main optical axis. According to one embodiment, the intermediate focus zone may be linear, triangular, rectangular, circular or a geometric shape whose number of sides may be at least five.

Thus, thanks to this arrangement, all emerging light rays are substantially symmetrical with respect to the main optical axis. According to one embodiment, the intermediate focus zone is in a plane passing through the main optical axis and the secondary optical axis. Thus, thanks to this arrangement, the set of emerging light rays 20 is substantially symmetrical with respect to the main optical axis. According to one embodiment, the intermediate focus zone comprises a symmetry of revolution with respect to the main optical axis. According to one embodiment, the intermediate focus zone may be annular.

Thus, thanks to this arrangement, the set of emerging light rays is substantially symmetrical with respect to the main optical axis. According to one embodiment, the second emergent surface comprises a set of ends.

Thus, thanks to this arrangement, the second emergent surface can be clearly defined. According to one embodiment, the lateral surface comprises a set of ends.

Thus, thanks to this arrangement, the lateral surface can be clearly defined. According to one embodiment, the intermediate focus zone is between the set of ends of the lateral surface and the set of ends of the second emergent surface.

According to one embodiment, the second emergent surface focuses light from the intermediate focus zone, with an angle of between 0 ° and 10 °, in particular between 0 ° and 5 ° and preferably between 0 ° and 3 °. ° with respect to the secondary optical axis. Thus, thanks to this arrangement, the light rays emerging from the second emergent surface emerge relative to the secondary optical axis. According to one embodiment, the secondary optical axis is between all the ends of the second emergent surface. Thus, thanks to this arrangement, the secondary optical axis is located inside the second emergent surface.

According to one embodiment, the secondary optical axis is normal to a portion of the second emergent surface. Thus, thanks to this arrangement, the determination of the direction of the light rays is facilitated. According to one embodiment, the secondary optical axis is normal to a portion of the second emergent surface and passes through the intermediate focus zone. Thus, thanks to this arrangement, the second emergent surface makes it possible to focus the light rays.

According to one embodiment, the lateral surface is configured to order the incident light rays at the first incident surface. Thus, thanks to this arrangement, the optical system makes it possible to restore the image of the light source.

According to one embodiment, the side surface is configured to reverse incident light rays to the first incident surface through the intermediate focus area. Thus, thanks to this arrangement, the optical system makes it possible to restore the image of the light source. Indeed, reversing and reordering the light rays 10 makes it possible to obtain an aplanatic system. According to one embodiment, the lateral surface is configured so that the light rays whose emission angle is close to the plane of section cut the light rays whose emission angle is close to the first incident surface at a point intersection between the second incident surface and the lateral surface. Thus, thanks to this arrangement, the light rays are inverted so as to obtain the image of the light source. According to one embodiment, the lateral surface is configured so that the light rays, whose emission angle is close to the plane of exposure, cut off the light rays whose emission angle is close to the first surface incident in the intermediate focus area between the second incident surface and the lateral surface. Thus, thanks to this arrangement, the light rays are inverted so as to obtain the image of the light source. Indeed, the intersection of the light rays 25 in the intermediate focus zone makes it possible to have an aplanatic system. According to one embodiment, the lateral surface has a convex portion. Thus, thanks to this arrangement, the light rays are directed towards the emergent surface, in particular towards the second emergent surface.

According to one embodiment, the first incident surface has a convex surface. Thus, thanks to this arrangement, the light rays can converge. According to one embodiment, the first incident surface comprises a first incident optical element. Thus, thanks to this arrangement, the light rays can be redirected. According to one embodiment, the second incident surface comprises a second incident optical element.

Thus, thanks to this arrangement, the light rays can be redirected. According to one embodiment, the optical system is made of polymer configured to allow easy replication of complex shapes by molding. According to one embodiment, the optical system is made of silicone.

Thus, thanks to this arrangement, the optical system can withstand high light densities. According to one embodiment, the silicone is configured to withstand light densities greater than 2 W / cm 2, in particular greater than 3 W / cm 2 and in particular greater than 4 W / cm 2 and 6 W / cm 2.

Thus, thanks to this arrangement, the structure of the optical material is not impaired by the high density of light emitted by the light source. According to one embodiment, the silicone is configured to withstand light densities whose wavelength range is less than 470 nm, in particular less than 460 nm and preferably less than 440 nm.

Thus, thanks to this arrangement, the optical system does not yellow in the presence of a high density of blue light. The present invention further relates to a light device for aligning a set of beams of light rays with respect to a projection axis and comprising at least one light source and at least one optical system according to the invention. According to one embodiment, the projection axis comprises an angle between 0 ° and 10 °, in particular between 0 ° and 5 ° and preferably between 0 ° and 3 ° 5 with the main optical axis of the optical system. According to one embodiment, the projection axis may be coincident with the main optical axis of an optical system. According to one embodiment, the light device comprises a plurality of optical systems according to the invention, the optical systems being arranged in a matrix. According to one embodiment, the matrix is monolithic. Thus, thanks to this arrangement, the arrangement of the plurality of optical systems is maintained in all circumstances, for example during transport or during assembly.

According to one embodiment, the light device further comprises a substrate. According to one embodiment, the light device further comprises a printed circuit. Thus, with this arrangement, electronic components can be assembled. According to one embodiment, the printed circuit comprises a plurality of light sources, each light source being disposed at the object focus of an optical system of the matrix. Thus, thanks to this arrangement, the light sources can be assembled with other electronic components. According to one embodiment, each light source is a light-emitting diode 3035228 20 Thus, thanks to this arrangement, the intensity of the light source can be graduated by varying the duty cycle of the current source and / or voltage . According to one embodiment, the light emitting diode emits a monochromatic wavelength range. According to one embodiment, the set of light-emitting diodes is configured to emit monochromatic and / or polychromatic light. According to one embodiment, the light device comprises at the output of the matrix a microlens integrator configured to homogenize the light.

Thus, thanks to this arrangement, the light device comprises a minimum geometric extent, that is to say that the divergence of the light beam is minimized, while ensuring a very good homogeneity of the light. According to one embodiment, the light device comprises, at the output of the microlens integrator, a condenser lens converging all 15 light rays. The present invention further relates to a light projector comprising a light device according to the invention, the light projector further comprises a projection lens, a set of filters configured to totally or partially filter the light emitted by the light device and / or or a mask configured to totally or partially mask the light emitted by the light device. Other features and advantages of the invention will appear better on reading the following description of an embodiment of the invention given by way of non-limiting example.

List of Figures The invention will be better understood with the aid of the detailed description which is set forth below with reference to the drawing, in which: FIG. 1 represents an example of a conventional collimator according to the state of the art ; FIG. 2 shows an example of the distribution of the peripheral and central light intensity represented in the form of an intensity diagram when the conventional collimator according to the state of the art is implemented; the light source having a square emitting surface; FIG. 3 illustrates an example of the distribution of the peripheral light intensity represented in the form of an intensity diagram when the conventional collimator 10 according to the state of the art is used; the light source having a square emitting surface; - Figure 4 shows an example of the light projector realized an embodiment; Figures 5 and 6 show a schematic example of the optical system according to embodiments; FIG. 7 shows a view from above of an exemplary optical system matrix according to one embodiment; FIG. 8 is a bottom view of an exemplary optical system matrix according to one embodiment; Fig. 9 shows an example of the optical system according to one embodiment; - Figure 10 shows a sectional view of the optical system according to one embodiment; FIG. 11 shows an example of an optical path in the optical system according to one embodiment; FIG. 12 illustrates an example of the optical system according to another embodiment; FIG. 13 represents an example of a light device according to one embodiment; FIG. 14 shows a sectional view of the optical system according to another embodiment; Fig. 15 shows an example of the distribution of peripheral and central light intensity shown as an intensity diagram when the optical system is implemented; the light source having a square emitting surface; and FIG. 16 illustrates an example of the distribution of the peripheral light intensity represented as an intensity diagram when the optical system is implemented. the light source having a square emitting surface. In the following detailed description of the figures defined above, the same elements or elements fulfilling identical functions may retain the same references so as to simplify the understanding of the invention. DESCRIPTION OF AN EMBODIMENT OF THE INVENTION GENERAL PRINCIPLE By optical system, it is understood in the present application a transparent part 20 within which light rays propagate in a controlled manner from one end of the optical system, called incident surface to an emergent surface. The light rays penetrate the optical system through an incident surface and eventually propagate by internal reflections on a side surface, and leave the optical system through the emergent surface. In practice, near the incident surface, is disposed a light source, for example of small size, such as a light emitting diode or a COB system (in English: "Chip-On-Board"). The light rays emitted by this light source propagate in the optical system of the incident surface towards the emergent surface and possibly via lateral surfaces located between the incident surface towards the emergent surface.

The general principle of the invention is based on an optical system 200, 300 of transparent material for wavelengths included in a set of beams of light ray and for aligning the set of beams of light rays with respect to a main optical axis 0 'from a light source 120 so as to obtain a clear image of the light source. To do this, the optical system 200, 300 must necessarily be aplanatic, that is to say that the system must be able to give a clear image of the light source 120 placed in its object focus. The optical system 200, 300 is configured to be stigmatic.

All the light rays coming from the focal point of the optical system converge at a single point which is the image focus, in other words the optical path between the object focus and the image focus is constant, whatever the trajectory followed by the light ray between these two points. In order to obtain a clear image, the optical system must also satisfy the condition of aplanetism (also known as the "condition of the Abbe sinuses"), that is to say that at any point object in the focal plane object of the optical system, in this case a light source 120, includes an image point in the image focus plane. In the example of Figure 1, there is shown a conventional collimator.

The conventional collimator comprises a cavity 910 configured to receive a light source 120 through an aperture 919. The rays emitted by the light source 120 are reflected by total internal reflection by a side wall to the surface of the light. emergence 950. The arrangement of the light source 120, the side wall and the emergence surface makes it possible to verify that the optical path, as previously mentioned, is constant. However, such an arrangement reverses the arrangement of the rays from the object focus which gives a blurred image. Indeed, the rays emitted by the light source 120 whose emission angle is high relative to the optical axis (and reciprocally close to the laying plane 941) will be reversed so that the emitted ray having the angle The largest emission with respect to the optical axis is closer to the optical axis than the emitted ray having the lowest emission angle 943. Therefore, the mathematical function which gives the height of the beam emerges depending on the opening angle of the incident ray, is decreasing. But to verify the condition of the Abbe sinuses, it is necessary that this function be increasing. Since the condition of the Abbe sinus can not be verified, it is impossible for the rays reflected by total internal reflection to form an image of the light source. As can be seen in FIGS. 2 and 3, the image of the light source 120 through the peripheral portion is not formed in the case of a conventional collimator. Indeed, the source is square and the intensity diagram is round. In Figure 3, we can see the intensity level gradually decrease from 0 ° to 20 ° and beyond. The object of the present invention is to provide an aplanetic optical system 200, 300 which makes it possible at the same time to respect the condition of the Abbe sinuses and to have a beam of light ray parallel to the optical axis at the output of the optical system 200 The invention achieves its object by the fact that the optical system 200, 300 comprises an emergent surface formed by a set of emerging optical elements, and a cavity 110 configured to receive a light source 120 and provided with an incident optical element so as to direct the light rays towards the emergent surface and a lateral surface 130 configured to reflect, by total internal reflection, the light rays towards the emergent surface. More particularly, the present invention makes it possible to form a sharp image by reorganizing the peripheral rays, that is to say by allowing emerging light rays whose emission angle is high relative to the optical axis, to be reversed. Thus the mathematical function which gives the height of the emergent ray as a function of the opening angle of the incident ray, is increasing, and therefore the condition of the Abbe sine can be fulfilled. Thus the invention greatly improves the geometric extent of the light flux by minimizing it and preserving a clear image of the light source 120. and by providing a monobloc optical system 200, 300 avoiding light losses between the parts. General Description of an Embodiment Referring to FIGS. 5 and 6, a light projector 600 made according to the invention can be observed.

As shown in FIGS. 5 and 6, the light projector 600 comprises a set of light sources 120 which emits beams of incident light rays towards an optical system 300 which incorporates the spirit of the invention. The optical system 300 represents a first stage of the light projector in the form of a monolithic matrix 610, ie formed integrally, and comprising at least two optical systems 300. In practice, the matrix may comprise forty-five optical systems 300, as shown in Figures 7 and 8. This first stage may be associated with a microlens integrator 620 configured to homogenize emerging light of the first stage. This intermediate stage, i.e., the microlens integrator 620, may be coupled to a biconvex optical element 630 so as to focus and generate a concentrated light beam. The light projector 600 thus enables the light beam coming from this light source to be re-projected in front of which various shutters, covers, and / or elements (represented by the reference 640) can be placed and allowing the realization of special effects. (Light box, color wheel, iris and / or Gobos for example) and / or an optical zoom 650 for projecting the light beam. The light source 120 defines a main optical axis O '. This optical system 200, 300 preferably made integrally of polymer and more exactly of silicone, comprises a main body 190. This arrangement has some advantages such as, for example, that of withstanding high density of blue light (between 2 W / cm 2 and 10 W / cm 2). The shape of the main body 190 of the optical system 200, shown in FIG. 9, has an outward appearance approximating the shape of a half-sphere more precisely, the shape of the main body 190 of the optical system 200, 300 is approaching of the form of a truncated half-circle, when the optical system 200, 300 is observed in profile, since the top of the semicircle can be truncated to form a laying plane 122 with a peripheral base 121 included in and / or on the laying plane 122 and on which the optical system 200, 300 can rest when it is placed. For the sake of clarity, the description of the geometric shape of the optical system 200, 300 has been simplified and reduced to the sphere term. According to some embodiments, the optical system 200, 300 may have a half-oval, half-parabolic and / or half-elliptical shape depending on the characteristics of the light source 120, the dimensions of the optical system 200, 300 and or the refractive index of the material used to form said optical system 200, 300.

As permitted by the sectional view in FIG. 9, the optical system 200, 300 comprises a set of surfaces and a cavity located between the laying plane 122 and the main body 190. The cavity 110 is configured to receive the source 120 through an opening 119 allowing access to the cavity 110.

The above-mentioned surface assembly includes incident surfaces, a side surface 130, and emergent surfaces. The optical system 200, 300 is oriented with respect to the light source 120 so that the incident beams arrive at the optical system 200, 300 at its incident surface with an angle relative to the optical axis of the source of light. 120. The incident surface completely or partially covers the cavity 110 and may be substantially flat or convex depending on the embodiments. The outer periphery of the optical system 200, 300 comprises a peripheral edge of substantially linear, circular, annular, rectangular or polygonal shape among others, and extends in a plane substantially perpendicular to the optical axis of the light source 120. This border may be formed by a second emergent surface. Figure 11 shows the path of a set of light beams emitted by the light source 120 within the optical system 200, 300 to provide a better understanding thereof. In the rest of this general description, the set of light rays emitted by the light source 120 will be differentiated into two subsets, or more precisely the light rays emitted by the light source 120 will be differentiated into central light rays and rays. side light 141-143.

The light source 120 is totally or partially admitted into the optical system 200, 300 via an opening 119 included in the laying plane 122 and allowing access to a cavity 110 formed inside. 200, 300. The cavity 110 is formed by a first incident surface 111 and a second incident surface 112. The first incident surface 111 is delimited by the second incident surface 112. This delimitation 5 is shown in FIG. in the form of a first common singular point and more particularly in the form of a first cusp 180. In practice, this delimitation may be in the form of a first singular common line and more particularly in the form of a a first cusp 180.

More precisely, the first singular point 180 is a first cusp 180, more precisely a first cusp 180 formed partially by the convex shape of the second incident surface. More specifically, the first singular line 180 is a first cusp 180, specifically a first cusp 180 formed partially by the convex shape of the second incident surface. The incident lateral light rays, that is to say the light rays incident on the second incident surface 112, are refracted towards the peripheral edge of the optical system 200, 300 or more exactly towards the peripheral emergent surface: second emergent surface 152 Indeed, the peripheral edge and the second emergent surface 152 are combined. The second emergent surface 152 thus receives, via the lateral surface 130, the lateral light rays incident on the second incident surface 112. The second emergent surface 152 is defined by a second optical element 154 having a curvilinear shape, more precisely a convex form. The convex shape of the second emergent surface 152 comprises a second singular point 170 making it possible to define the second emergent surface 30 of a first emergent surface. The second singular point 170 is common to the second emergent surface and the first emergent surface, ie the second emergent surface and the first emergent surface comprise a second common singular point 170. In practice, this delimitation may be presented under the form of a second singular line 170 to the second emergent surface and the first emergent surface, that is to say the second emergent surface and the first emergent surface comprise a second singular common line 170.

More precisely, the second singular point 170 is a second cusp point 170, more precisely a second first degree cusp 170 formed partially by the convex shape of the second emergent surface. More strictly, the second singular line 170 is a second cusp 170, more specifically a second cusp 170 first formed partially by the convex shape of the second emergent surface. The inner wall of the cavity 110 is configured to direct, by total internal reflection, the incident lateral light rays from the second incident surface 112 to the second emergent surface 152. More precisely, the lateral surface 130 is configured so that the radii lateral luminaires 141, whose emission angle is close to the laying plane a, cut off the lateral light rays 143 whose emission angle is close to the end of the first incident surface y at a first point of intersection 149 located between the second incident surface 112 and the lateral surface 130 with reference to the optical path of the light rays. To do this, the second incident surface 112 of the second incident element and the lateral surface 130 can be calculated so as to focus the light rays of the main object focus towards the intermediate focus zone.

In other words, the optical system is configured such that the greater the emission angle y of a light beam 143 from the light source is away from the maximum opening angle M of the source of light, plus the respective emerging light beam has a distance c close to the main optical axis. In contrast, the optical system is configured such that the higher the angle of emission of a light ray 141 from the light source is close to the maximum aperture angle M of the light source, plus the respective emerging light ray 141 at a distance away from the main optical axis. In other words, the distance between the emergent light ray 141 and the main optical axis 30 is greater than the distance c between the emerging light ray 141 and the main optical axis and the emission angle α between the light ray at the second incident surface and greater than the emission angle y between the light beam and the second incident surface.

In other words, the optical system is configured in such a way that the distance of an emergent light ray with respect to the main optical axis increases as a function of the increase in the emission angle of the respective light beam. of the light source, and reciprocally the distance of an emerging light ray with respect to the main optical axis decreases as a function of the decrease in the emission angle of the respective light beam from the light source. The calculation consists in equating the second incident surface of the second incident optical element, the lateral surface of the main body and the second emergent surface of the second optical element emerge with the aim of focusing the emerging light rays and focused light rays in the intermediate focus zone. The set of equations thus produced is coupled. The second incident surface of the second incident optical element can be left as a free parameter, which will be adjusted in order to reach the condition of the Abbe sinuses. An intersection point is formed in the intermediate focus zone 520 of the second emergent optical element 154. More strictly, the point of intersection of the rays incident to the first incident surface 111, and reflected by the lateral surface 130, lies in the intermediate focus area 520 so that the image of the light rays refracted by the side surface 130 is formed at infinity, i.e., the refracted light rays from the side surface 130 emerge with a angle between 0 ° and 10 °, in particular between 0 ° and 5 ° and preferably between 0 ° and 3 ° with respect to the main optical axis O '. The second emergent optical element 154 may also have a curvilinear shape, more specifically a convex shape, and more particularly the second emergent optical element 154 may have a shape of a convex optical element configured to allow the convergence of the incident light rays 3035228. the second incident surface 112 of the second incident optical element 114. According to another embodiment 300, FIG. 12, the first emergent optical element 153 may have a curvilinear shape, more specifically a convex shape. More exactly, the first emergent optical element 153 may have a shape of a convex optical element configured to allow emergent rays to emerge with an angle of between 0 ° and 10 °, in particular between 0 ° and 5 ° and preferably between 0 ° and 3 ° with respect to the main optical axis O '. Thus, by virtue of this arrangement, the first incident optical element and the first emergent optical element form a biconvex aspherical optical element allowing the optical system to be aplanar for incident light rays at the first incident surface. The two parameters which are the radius of curvature of the curvilinear shape of the first incident optical element and the radius of curvature of the curvilinear shape of the first optical element emerge as well as the equations for verifying that the optical path of a light ray remains constant during the crossing of the biconvex aspheric optical element and the conditions of the Abbe sinus are determined using optical design software such as ZEMAXTM software and / or Code VTM 20 The second optical element emerges 154 also includes the second singular point 170, where more precisely the second singular line at one of these ends thus delimiting the second emergent surface of the first emergent surface. More precisely, the second singular point is a second cusp 170, more precisely a second cusp of first degree 170 formed partially by the convex shape of the second emergent optical element 154. Of course, in practice, the second singular line is a second cusp 170, more precisely a second cusp 170 formed partially by the convex shape of the second emerging optical element 154.

The light rays incident on the incident surface, or more precisely incident to the first incident surface 111, will be qualified in the remainder of the description as the central light rays. The central light rays incident on the first incident surface 111 are thus refracted towards the emergent surface and more particularly towards a first emergent surface 151. The first emergent surface 151 is close to the second emergent surface 152. According to another embodiment, the first emergent optical element 153 may have a curvilinear shape, more specifically a convex shape. More exactly, the first emergent optical element 153 may have a shape of a convex optical element configured to allow the emerging light rays to emerge with an angle of between 0 ° and 10 °, in particular between 0 ° and 5 ° and preferably between 0 ° and 3 ° with respect to the main optical axis O '. The first emergent optical element 153 comprises the second singular point 170 at one of these ends thus making it possible to define the first emergent surface of the second emergent surface. More precisely, the second singular point is the second cusp 170, more precisely the second first degree cusp 170 formed partially by the convex shape of the first emergent optical element 153.

Of course, in practice, the first emergent optical element 153 comprises the second singular line 170 at one of these ends thus making it possible to define the first emergent surface of the second emergent surface. More exactly, the second singular line is the second cusp 170, specifically the first cusp 170 formed partially by the convex shape of the first emergent optical element 153. In this embodiment, the optical element biconvex aspherical further comprises an object focus located in the vicinity of the optical axis and the laying plane 122, or more simply, said hearth is located in the vicinity of the light source. More rigorously, the biconvex aspheric optical element 30 comprises a main object focal plane. Thus, thanks to this configuration, any image formed by the biconvex aspheric optical element of the light source 120 is clear.

Thus, the configuration of the first emergent optical element 153 and the first incident optical element 113 allow the formation of an object focus of the optical system 200, 300 as well as a main object focal plane. In this way, when a light source 120 is placed in the vicinity of the object focus or more closely in the vicinity of the main object focal plane, all rays from the light source 120 and incident to the first incident surface 111 are refracted to the first optical element emerges 153 so as to emerge with an angle of between 0 ° and 10 °, in particular between 0 ° and 5 ° and preferably between 0 ° and 3 ° with respect to the main optical axis O '.

FIGS. 15 and 16 illustrate the results obtained with one of the optical system embodiments 200, 300. The practical results are very close to the theoretical results and show that the normalized intensity peak at 1 lumen emitted is 10 cd and that the intensity remains constant up to 7 ° with respect to the main optical axis O '. Beyond 10 ° there is almost no light left. Figure 16 demonstrates that the second emergent surface 152 forms an image of the light source 120. Indeed, the light source 120 is square and the intensity diagram is square as well.

Claims (15)

CLAIMS1) Optical system (100) of transparent material for wavelengths included in a set of beams of light rays (141, 142, 143) and for aligning said set of light beams (141, 142, 143) with to a main optical axis (O ') from a light source (120), said light source (120) including a transmission center located on the main optical axis (O') and at least one surface emitting light rays intended to be diffused in a space of refractive index greater than or equal to one; said optical system (100) comprising: a cavity (110); the cavity (110) being configured to receive said light source (120) through an opening (119) allowing access to the cavity (110) at a positioning location for receiving fully or partially the light source and comprising a first incident surface (111) configured to refract the light rays from the light source (120) to a first emergent surface (151) and a second incident surface (112) extending over the periphery of the positioning location between a first edge (121) and a second edge adjacent to the first incident surface (112) and configured to refract light rays from the light source (120) to a second emergent surface (152); ); and a side surface (130); the lateral surface (130) defining an outer wall extending between the first edge (121) of the second incident surface and the second emergent surface; the lateral surface (130) being configured to reflect by total internal reflection the light rays from the second incident surface (112) to an intermediate focus zone of the second emergent surface (152) disposed between the lateral surface (130) and the second incident surface (112); characterized in that: - the second incident surface (112) and the lateral surface (130) are configured to define an intermediate focus area (30) disposed between the side surface (130) and the second incident surface (112), the intermediate focus area representing the focus area of the second emergent surface (152). 5 2) optical system (100) according to claim 1, which being configured such that the light rays from the light source whose emission angle is close to the maximum aperture angle (M) of the light source emerging from the second emergent surface near the peripheral end of the optical system and the light rays from the light source 10 whose emission angle is furthest from the maximum aperture angle (M) emerge from the second emergent surface near the main optical axis (O '). An optical system (100) according to claim 2, wherein the side surface is configured to reverse incident light rays at the first incident surface via the image intermediate focus area. An optical system (100) according to any one of claims 1 to 3, wherein the assembly consisting of the second incident surface (112), the lateral surface (130) and the second emergent surface (152) is aplanatic. An optical system (100) according to any one of claims 1 to 4, wherein the first incident surface (111) is defined by a first incident optical element and the first emergent surface (112) is defined by a first optical element emerging, the first incident optical element and the first emerging optical element forming a biconvex aspherical lens. An optical system (100) according to claim 5, wherein the biconvex aspherical lens is aplanatic. An optical system (100) according to any one of the preceding claims, wherein the lateral surface is configured to reflect by total internal reflection the light rays from the second incident surface towards the second emergent surface so that the light rays emerging from the second emergent surface are included in an angle between 0 ° 3035228 and 10 °, in particular between 0 ° and 5 ° and preferably between 0 ° and 3 ° with respect to the main optical axis and the emerging light ray of the first emergent surface. An optical system according to any one of the preceding claims, wherein the second emergent surface (152) is disposed laterally with respect to the first emergent surface (151). An optical system according to any one of the preceding claims, wherein the first emergent surface (151) and the second emergent surface (152) comprise a common boundary (170). 10) Light device for aligning a set of beams of light rays with respect to a projection axis and comprising at least one light source and at least one optical system according to any one of claims 1 to 9. 11) A light device according to claim 10, comprising a plurality of optical systems according to any one of claims 1 to 9, the optical systems being arranged in a matrix (610). 12) Light device according to claim 11, wherein the matrix (610) is monolithic. 13) Light device according to any one of claims 10 to 12, wherein the light device further comprises at the output of the matrix 20 microlens integrator configured to homogenize the light. 14) Light device according to any one of claims 10 to 13, wherein the light device further comprises at the output of the microlens integrator a condenser lens converging all the light rays. 25 15) A light projector comprising a light device according to any one of claims 10 to 14, the light projector further comprises a projection lens, a set of filters configured to totally or partially filter the light emitted by the light device and or a cache configured to totally or partially mask the light emitted by the light device.