DE2653030A1 - Floodlight twin reflector construction - has parabolic sections mounted around light source to reduce multiple reflections - Google Patents

Abstract

A reflector for a lamp has a min reflector in the form of a trough of parabolic section with the light source at its focal point and with a second reflector within the first reflector in front of the light source. The position of both parabolic sections (13, 14) of the out plane of the second reflector (7) is mounted on part of the branch arm of a parabolic. The axis of this parabola is the main axis (2) of the light beam and has the emission zone (5) of the source situated at its focal point. The lamp can be mounted on a mast for floodlighting an area such as a football pitch.

Description

reflector

The invention relates to a reflector device which has a first Has reflector in the form of a channel or trough, in the cross section of which there is a main axis of a wave propagation bundle that emanates from the reflector, wherein the first reflector has a parabolic cross-section, in whose focal point the emission area is located a source generating the wave flux is located, while a second reflector placed inside the first reflector in front of the source through which the opening that part of the wave flux is controlled which is at a fixed angle] through two generators is limited, which emanate from the emission area and to the lower edges of the first reflector, with a sectional plane of the second reflector, which contains the major axis of the expanding fret, with at least two Parabolic sections are formed whose common focus is in the emission area lies.

It has long been known that the radiation flux from a source, in particular a light source, concentrated in a beam controlled in its opening angle can be if an optic with a parabolic or elliptical Cross-section used and the light source in the focal point of this cross-section is set.

It is also known to use secondary optics to prevent the Reduce the dimensions of the main optics. In the known devices, that is in the case of optics composed of main and secondary optics, it allows relative Position of the two optics never at the same time, a satisfactory convergence of the output To achieve beam to exclude the multiple reflections and to the greatest extent to use the river given off to the rear without at least some of the rays go through the source again.

The multiple reflections result in energy radiation losses in the form of useless heat generation in the optics and in the source lead to one poor energy utilization, and secondly, the problem of recovery of the Energy flow for the case of a linear source and a reflector in the form of a Gully or trough is very important. In such a case, the opening angle is from the source radiated river in all planes of intersection between the two Ends of the trough in any case 3600, so that the amount of radiation emitted to the rear is quite significant. In the case of certain known reflectors, this is transmitted to the rear Flow by increasing the dimensions of the optics or countering that again the multiple reflection is exploited, which causes the difficulties mentioned above still increased.

The object of the invention is to provide one of a main reflector and a Secondary reflector to create composite device with the effective use of the Beam opening angle can be controlled at simultaneous decrease of the reflective surfaces, especially avoiding multiple reflections as far as possible should be.

In her best elaborated embodiment of the invention This device also allows the use of the delivered to the rear Radiation flux without a critical increase in the reflections and without changing the Control of the bundle opening.

In a modified embodiment, the invention can be a secondary radiation, especially of light, caused in a particular direction that deviates from the main emission axis.

The reflector device according to the invention is essentially characterized by this characterized in that the position of the two parabolic sections of the cutting plane of the second Reflector is derived from the location of a part of a branch of a parabola, whose Axis is the main axis of the emerging bundle and the emission zone at the focal point the source has by pivoting the respective parabolic load section around the focal point.

The invention will then be illustrated using exemplary embodiments with reference to the drawing described in more detail. They show: FIG. 1: a section through a reflector arrangement according to the invention. It is a cross-section in any plane between the two ends; FIG. 2: a detail from FIG. 1; FIG. Fig. 3: a Representation as in FIG. 1 for a modified embodiment; Fig. 4: a detail from FIG. 3.

The reflector device according to the invention consists of a first Reflector, which is designed in the form of a trough and whose cross section 1 a Main axis 2 for the emission of the emitted wave bundle 3. The cross section 1 of the first reflector has a parabolic area 4. The emission zone 5 of the source 6 preferably falls into the focal point 5 of the parabolic section 4 of the first reflector 1. The device has a second reflector 7 within the first reflector 1, which lies in front of the source 6 and with which the opening angle of a part 8 of the wave flux can be controlled, which is defined at a fixed angle defined by the Generating 9 and 10 is limited, which emanate from the emission area 5 and above the lower edges 11, 12 of the first reflector 1 run. The second reflector 7 is located in a sectional plane that defines the axis of propagation 2 of the radiation beam 3 contains, and is formed from two parabolic sections 13, 14, the common Focal point is in or near the emission zone 5.

The two elongated wings that form the reflector 7 are for example by riveting to the end walls (not shown) of the first Reflector-forming trough attached.

As shown in FIGS. 2 and 4, the position of the parabolic sections is directed 13 and 14 of the sectional plane of the second reflector 7 after the position of a section 15 of a parabolic branch 16, the axis 2 of the beam 3 and as the axis The focal point has the emission zone 5 by placing this section of the parabolic load 1+ around this focal point 5 is pivoted by a certain angle d, which depends on the desired aperture angle / 9 for part 8 of the beam flux. As is particularly clear from Figs. 2 and 4, there is a relationship between the opening angle of part 8 of the beam flux and the pivot angle of one of the parts 13 or 14 of the parabola in that the opening angle decreases to the extent (starting from from the initial opening angle, which is caused by the design of the parabolic sections of the reflector 7 is specified), as is the pivot angle d of the sections under consideration 13 and 14 gets bigger.

Fig. 1 shows a pivoting of the two parabolic sections, have the same length, at the same angle e (obtained reflector, where the obvious relationship between the opening angle of the area 8 for the beam flux and the pivot angle of the two parabolic sections expressed mathematically thereby can be that the sum + 2c (is constant and more precisely equal to the opening angle of the second reflector before pivoting the two parabolic sections. on the other hand the parabola sections 13 and 14 in FIG. 1 are formed by the same parabola that is, they have the same mathematical parameters. The cross section the first reflector has two hyperbolic sections near its apex 17 18, 19 symmetrically to the vertex 17. The cross-section of the two hyperbolic sections 18 and 19 has the emission zone 5 as its first focal point. The second focal point 20 and 21 of the hyperbolic sections 18 and 19 is chosen so that the reflected Beams 22 and 23 of each of the hyperbolic sections 18 and 19 between the second Reflector 7 and the lower edges 11 and 12 of the first reflector passes. The apex 17 of the cross section of the first Reflector 1 can be a Have opening, but preferably has a portion as shown in Figs. 1 and 3 24 in V-shape, the branches of which have been chosen in such a way that the rays, which, starting from the emission zone 5, are reflected there into the exiting Beam 3 with a single reflection 25 on the surface of the first reflector 1 will be broadcast.

3 and 4 relate to a modified embodiment the reflector device according to FIGS. 1 and 2, in which the two parabolic sections 13 and 14 in the sectional plane of the second reflector 7 in at least one of the following three properties differ from each other: At the distance of their front end point 13a, 14a from the main axis, in the value of the pivot angle about the focal point 5 and in the value of the parameter that defines the parabola from which the two emerged is.

The parabolic sections 13 and 14 preferably differ at least by the value of the angle through which they were pivoted about the focal point, and possibly also in the parameter by which the parabola is defined from which the two are derived.

Define a reference plane with right-angled coordinates, in which the main axis 2 is the X-axis on which the Y-axis is perpendicular and through the focal point 5 goes, which is then the ordinate axis, and one continues the indices i and f to indicate the sizes before and after the pivoting of the parabolic sections (i = start, f = end), the values = = swivel angle of the parabola section 13 = = Swivel angle of the parabolic section 14 P1 = parameters of the parabola from which section 13 is taken, P2 = parameters the parabola from which section 14 is taken, the values 41 and 2 (positive) the distance between the front end points 13a and 14a of the respective parabolic sections 13 and 14 to the major axis, where # 1i, # 2i and # 1f, # 2f are the values of the respective Distances before and after the pivoting of the parabolic sections are. Here is the 3 and 4 shown variant so that the three following conditions are fulfilled: If α1 = α2 and P1 = P2 then # 1f # 4 # 2f if α1 = α3 and # 1f = # 2f then P1 # P2 if Pl = P2 and # 1f = 7? 2f then ct1 # α2.

If, on the other hand, ß1 1 and / 4 2 denote the sections of the opening of the exit area 8 which lie on both sides of the main axis 2 against the parabolic sections 13 and 14 (so that A and / 2f =), with simple trigonometry and the basic equation of the parabolas with the previously specified designations, the following equation structure or a1 = ß11 - ß1f and = 2 = ß2i - ß2f so that and finally This expression is the mathematical form of the relationship between the swivel angles Ct1 and% of the parabolic sections 13 and 14 and the desired opening angle (expressed in sizes that only depend on the shape and length of the parabolic branches that are used for the construction of the second reflector 7 selected).

The reflector device of this embodiment can, for example, if it is attached to a pole, a football field and at the same time the Illuminate the mast base.

The invention is not limited to the exemplary embodiments described limited, with which reflectors in trough or trough shape for elongated light sources are described, but can also be used for all variants that follow equivalent to the laws of geometrical optics with the device described are.

It is also understood that the terms "focus", "parabolic", "Hyperbolic" is not to be understood in the strict mathematical sense. So can For example, the surfaces designated as parabolic or hyperbolic and made up of adjoining, consist essentially flat facet sections that are tangential to a mathematical parabolic or hyperbolic curve are adapted.

Claims (8)

PATENT CLAIMS Reflector device for the concentration of a Beam with a first reflector in the form of a channel or trough in which Cross-section is a main axis of a bundle of rays emanating from the reflector goes out, wherein the first reflector has a parabolic cross-section, in the focal point the emission range of a source generating the wave flux of the beam located, while a second reflector inside the first reflector in front of the Source is attached through which the opening of that part of the wave flow is controlled, which is limited at a fixed angle by two generators, the start from the emission area and run to the lower edges of the first reflector, wherein a plane of section of the second reflector, which is the major axis of the propagating Contains bundle, is formed with at least two parabolic sections, the common Focal point is in the emission range, characterized in that the position of the two Parabolic sections (13, 14) of the sectional plane of the second reflector (7) from the position a part (15) of a branch (16) of a parabola is derived, the axis of which is the The main axis (2) of the exiting bundle (3) and the emission zone at the focal point (5) of the source by pivoting the respective parabola section (13,14) the focal point (5). 2. erection according to claim 1, characterized in that the cross section of the first reflector (1) in the vicinity of its apex (17) has two hyperbolic sections (18,19) symmetrically to the vertex (17). 3. Apparatus according to claim 2, characterized in that the cross section each hyperbola section (18, 19) has its first focal point in the emission zone (5) has, while the respective second focal point (20,21) is chosen such that the reflected bundles of rays (22,23) of both hyperbolic sections (18,19) between the second reflector (7) and the lower edges (11, 12) of the first reflector (1) go through. 4. Device according to one of claims 1 to 3, characterized in that that the apex (17) of the cross section through the first reflector (1) is V-shaped Has training, the branches of this V-area (24) are chosen such that the rays emanating from the emission zone (5) and reflected at them with the Beam (3) by a single reflection (25) on the surface of the first reflector be united. 5. Device according to one of claims 1 to 4, characterized in that that their reflection surfaces are formed by essentially flat facet surfaces are tangential to the mathematically defined curves of the reflection surfaces are adapted. 6. Device according to one of claims 1 to 5, characterized in that that the two parabolic sections (13, 14) in the cutting plane of the second reflector (7) differ from one another by at least one of the following three properties: the distance (721f'7t2f) to the main axis (2) of its foremost points (13a, 14a) den Angle (X1, A2) of their pivoting around the focal point (5), the parameter value (P1, P2), by which the parabolas are defined. 7. Apparatus according to claim 6, characterized in that the two Parabolic sections (13, 14) different angles (α1, α2) of their pivoting around the focal point (5). 8. Apparatus according to claim 7, characterized in that the two Parabola sections (13, 14) also differ in their parameter values which determine the parabola (P1, P2) differentiate.