DE202015104936U1 - reflector - Google Patents

Abstract

Reflector which is fanned around a central, in cross-section circular support element (8) between a fanned and a collapsed state, with a plurality of reflector segments (1) movably mounted relative to each other about a common axis of rotation (12) on the carrier element (8). which are stacked in the collapsed initial state in the direction of the axis of rotation (12), the stack having a top (3) and a bottom reflector segment (2), and wherein each of the reflector segments (1) in a fanned-out state in which the reflector segments ( 1) form the reflector, forms a reflection surface, characterized in that in the fanned-out state, the reflection surfaces of all reflector segments forming the reflector (1) are identically shaped and arranged rotated around the rotation axis (12).

Description

The invention relates to a reflector for light waves, electromagnetic waves or acoustic waves, which is fan-foldable and fan-foldable between a fanned out and a collapsed state about a central carrier element which is circular in cross-section. The reflector has a curved, three-dimensional reflector surface in the fanned-out state and can be used in particular for lighting purposes in photography, film and interior spaces, for the transmission and reception of radio waves, for the collection of solar energy as well as for the transmission and reception of sound.

At the beginning of flash photography, small reflectors were constructed of differently shaped, superimposed segments rotatable around a light source ( US 1,813,102 . DE 469 116 A ). Later, there have been developments of solar reflectors and satellite antennas with a rotational mechanism in which a rotationally symmetric, parabolic shape is desired, but has also been in the fields until today ( US 7,014,329 . 6 ) no similarly simple, cheap and fundamentally better solution developed.

Collapsible reflectors, in particular those for light sources, are today usually constructed of a fabric material with a support frame according to the principle "umbrella".

• • Der Reflektor ist nicht nah am Objekt positionierbar (Mittelstrebe und Lichtquelle/Blitzgerät befinden sich zwischen Reflektor und beleuchtetem Objekt),
• • es ist keine Zentrierung der Lichtquelle in der Rotationsachse (12) möglich, da dort die Mittelstrebe verläuft,
• • die Spannungskonstruktion im Reflektor stört die Lichtformung,
• • das Gehäuse der Lichtquelle und dessen Aufhängung werfen Schatten auf das Motiv,
• • es ist keine Positionierung der Lichtquelle nahe am Reflektorzentrum möglich, da dort die Streben zum Spannen verlaufen,
• • der Stoff (das Gewebematerial) kann Spannungswellen werfen und durchhängen,
• • es ist nicht möglich Diffusoren oder andere Lichtformer über den Reflektor zu spannen.

This has among others the following disadvantages:

• • The reflector can not be positioned close to the object (center strut and light source / flash unit are located between the reflector and the illuminated object),
• • there is no centering of the light source in the rotation axis ( 12 ) possible because there is the center strut,
• • the tension construction in the reflector disturbs the light shaping,
• • the housing of the light source and its suspension cast shadows on the subject,
• It is not possible to position the light source close to the reflector center, because there the struts extend for clamping,
• • the fabric (the fabric material) can throw and sag stress waves,
• • it is not possible to stretch diffusers or other light shapers over the reflector.

There are elaborate constructions of fabric material that prevent some of these disadvantages ( US 3,286,259 A . DE 196 18 434 ).

The invention has for its object to develop reflectors form the desirable light characteristics, while quickly and easily assemble and disassemble, are stable, portable and inexpensive to manufacture.

The object is achieved with a device having the features of claim 1.

Accordingly, the reflector according to the invention can be fan-shaped between a fanned-out and a fanned-out state about a central, circular cross-section support element. It has a plurality of reflector segments movably mounted relative to each other about a common axis of rotation on the carrier element, which are stacked in the converged initial state in the direction of the axis of rotation. The stack of reflector segments has an uppermost and a lower reflector segment. In a fanned-out state in which the reflector segments ( 1 ) form the reflector, each of the reflector segments forms a reflection surface. These reflection surfaces of each reflector segment then together form the three-dimensionally shaped, typically dish-shaped or bowl-shaped, reflector surface of the reflector with which it reflects corresponding light waves, electromagnetic waves or acoustic waves.

The special feature of the reflector according to the invention is that in the fanned-out state, the reflection surfaces of all the reflector segments forming the reflector segments are identically shaped and arranged rotated about the axis of rotation. Identically shaped in this context means an identical shaping of the reflection surfaces according to their contour and curvature. Possible differently introduced into the reflecting surfaces of different reflector segments structures such. Guide slots for fasteners, so lead in this sense not to a non-identical shape of the otherwise contour and curvature identically formed reflecting surfaces.

If the reflector segments are to elastically deform under tension when the outermost reflector segments are connected and the target is a three-dimensional reflector which is as rotationally symmetrical as possible, it is important, as the inventor has recognized, that all reflector segments have substantially the same shape and symmetrical about the reflector Rotation axis the same stresses arise at the same points. This is not possible if, in the fanned-out state, one of the reflector segments has a different shape of its reflection surface.

In particular, each reflector segment in the fanned-out state of the reflector can advantageously be used when the two outermost reflector segments are connected to one another Reflecting surface of the reflector to form and close, in a reflection surface of the reflector segments forming region, with a first edge below and with a second edge over the respective adjacent segments.

The fact that unlike in the prior art ( DE 469 116 A 2 . US 2,806,134 A . GB 2 272 331 A ) none of the reflector segments along the axis of rotation is placed above or below all others further contributes to a uniform to the best standards, rotationally symmetric shape of the reflector.

In the solution according to the invention, therefore, in particular each reflector segment lies in the fanned-out state along the axis of rotation from the center point to the outer edge of the reflector between the adjacent reflector segments. For this purpose, each reflector segment can have the same shape.

In the solution according to the invention, in particular and advantageously adjacent reflector segments are connected to one another, both in the stack of the fan-shaped reflector segments and in the fanned-out state. Only the uppermost and the lowest reflector segment are unconnected in the collapsed state, are connected to each other only after fanning for the final formation of the reflector.

Furthermore, in the reflector according to the invention, the reflector segments, each with a first arm and a second arm engage around the support member, in which case a part of the first arm of the uppermost reflector segment is arranged under a part of the second arm of the lowermost reflector segment. As a result of this refinement, when the reflector is fanned out, each of the reflector segments lies below with a first edge and with a second edge above each adjacent reflector segment.

The arms, that is to say the first arm and the second arm of a reflector segment, can be designed in particular as ring segments of a ring which is completely divided perpendicular to the circumferential direction.

The arms, that is to say the first arms and / or the second arms, can furthermore each have at least one recess, and the recesses can be arranged such that they are aligned one above the other in the fanned-out state, so that a locking pin can be pushed through the recesses. Thereby, the reflector can be locked in the fanned-out state in a simple manner, so that all reflector segments are fixed.

This is particularly simple and flexible, if, as it provides an advantageous embodiment of the invention, each reflector segment along the first arm and the second arm, the support member circumferentially, a plurality of recesses which at an angular distance of 360 ° divided by the number of Reflector segments are arranged.

In addition, then, the support member may also have at least one opening which is aligned in the fanned-out state with the recesses in the reflector segments and through which the locking pin can be inserted so as to fix the reflector segments on the support member.

If, as an advantageous development of the invention provides, one of the reflector segments is fixed to the carrier element at at least one point, this facilitates the fan-out and "stretching" of the reflector.

Advantageously, each reflector segment has at least one radially outwardly arranged stop device for an adjacent reflector segment, which stops the adjacent reflector segment when fanning in an overlapping position. This ensures that the reflector can be easily constructed by fanning out, without the reflector segments would cumbersome to arrange individually. Radially outside in this context means at one with respect to a radial direction of the circular support member outboard position of the reflector segments.

In particular, the reflector segments are inherently rigid elements that can deform elastically under tension. The reflector segments can be formed in particular from plastic as sheet-like elements or as a metal.

The reflector segments may advantageously be flat with their reflection surfaces in a collapsed initial state, i.e., flat. to be flat and unconscious. This provides the advantage that the segments lie one above the other in the collapsed state of the reflector in low pile height and thus the reflector in this state is very compact and therefore easy to stow and transport. However, the reflector segments may also already in the condensed state have curved or curved reflecting surfaces or reflecting surface sections, in order, for. For reflectors with large diameter to achieve sufficient stability and rigidity in the fanned-out state.

The invention enables a very simple and inexpensive construction for a reflector rotatable, in a starting position flat reflector segments, cut, milled or stamped elastic plates or sheets may consist. It avoids the aforementioned disadvantages of the known from the prior art reflectors.

Seven embodiments of the invention are explained below with reference to drawings, in which:

1a : A representation of a reflector constructed according to the invention with reflector segments separated from one another in a flat and fanned out propagation to show the overlapping arrangement of the individual reflector segments;

1b : a representation comparable to 1a however, a prior art reflector having a top and a bottom reflector segment;

2a : a spanned reflector of the invention design in a front view;

2 B : a cross-section of the illustration 2a ;

3a an example of a single reflector segment for a reflector according to the invention;

3b : an example of another, in a reflector according to the invention to a reflector segment according to 3a adjacent reflector segment; and

4 : a side detail view of a support element of a reflector according to the invention in a fanned reflector

In the figures, a possible embodiment of a reflector according to the invention is shown in various views, partly with comparisons of the prior art for comparison. The figures are as the essential and inventive features of this embodiment showing schematic representations, but in no way as a full-fledged design drawings to understand. Also, the drawings are not about the only possible embodiment of the invention, but merely an exemplary embodiment.

1a is a frontal view of fanned, in this illustration, however, not interconnected reflector segments 1 a reflector according to the invention, wherein the reflector segments in an angular ratio of 360 ° divided by the number of reflector segments about the axis of symmetry 12 (see 2 B ) are placed flat on top of each other so that each reflector segment 1 in each case one visible in the figure and in plan view of the reflector surface of the reflector leading edge 4 over a trailing edge 5 from an adjacent reflector segment 1 lies.

1b illustrates the disadvantage of a reflector of the prior art. For comparison, here are the same reflector segments 1 as in 1 each stacked in a continuous stacking direction. It can be seen that this is a topmost reflector segment 3 with both edges, leading edge 4 and trailing edge 5 , over and a low reflector segment 2 with both edges, leading edge 4 and trailing edge 5 under all other reflector segments 1 lies. If now the reflector segments 1 . 2 . 3 are interconnected with each other in their radially outer regions, a non-ideal rotationally symmetric reflector is generated in this arrangement, as the deforming the reflector segments 1 . 2 . 3 to the three-dimensional shape obtained voltages due to the different mounting positions, in particular of the lowermost reflector segment 2 and the uppermost reflector segment 3 not uniformly distributed over the reflector surface occur.

2a is a front view of a clamped reflector with a circular cross-section support element 8th , This has in the embodiment shown a recess 9 for attaching a polygonal or round locking pin 15 on, by corresponding recesses in all reflector segments 1 is to push through. This will be the reflector segments 1 in the angular ratio of 360 ° divided by the number of reflector segments 1 and thus also the carrier element 8th even symmetrical about the axis of rotation 12 locked.

The carrier element 8th is about the axis of rotation 12 hollow and may in particular have a bayonet or clamping mechanism for recording studio flashes. On the locking pin 15 in particular, a smaller reflector 13 be arranged or fixable, in this way the central opening in the support element 8th in which, as mentioned above, a light source can be arranged, covers and reflects the light emanating from the light source on the reflecting surface formed from the visible reflection surfaces of the reflector segments and thus avoids direct illumination of the object to be illuminated. The smaller reflector 13 In this case, it can also have a certain, in particular diffuse, transparency, so that it allows light components to pass in the direction of the object to be illuminated, but this diffuses or diffuses. This smaller reflector 13 can in particular via a displacement of the Arretierstifes 15 in the axial direction or by shifting the smaller one reflector 13 on the locking pin 15 be adjusted and adjusted in its position relative to the light source in the center of the bowl-like reflector. This allows a specific influence on the light characteristics of the illumination generated by the reflector. Will namely the smaller reflector 13 moved closer to the light source, arrives at a partially diffusely permeable smaller reflector 13 a higher proportion of light diffuses, but still directly to the object to be illuminated, so that a harder light is produced. Will the smaller reflector 13 further out, so positioned away from the light source, the light is correspondingly softer. The smaller reflector 13 For example, it may be a flat, eg round, disc, eg of an opaque plastic material. In particular, the small reflector 13 also detached from the embodiment described here in a reflector for the application, not necessarily on a locking pin 15 but can also sit on another pin-shaped carrier, which does not perceive any additional locking function.

As in particular in 2a can be seen, the individual reflection surfaces of the reflector elements are the same, that is formed substantially identical.

The visible edges 4 the reflector segments 1 each have the same curve and the invisible edges 5 overlap at the back of the reflector. By the shape of the reflector segments 1 can be different curvatures 19 generate for the reflector in the fanned-out state. The overlaps allow a high dimensional stability.

2 B is a cross section of 2a , with a possible curvature 19 and a smaller reflector 13 moving in the direction of the axis of rotation 12 over the locking pin 15 is displaceable. This little reflector 13 reflects, as already mentioned, the light from the light source in the fanned reflector and direct light rays on the object are scattered or prevented.

3a is an example of a single reflector segment 1 , At a lower or inner end are the carrier element 8th rotatable embracing arms 17 . 18 to see. In this example, the reflector segment has 1 eleven recesses 6 which is distributed around the support element, also along the arms 17 . 18 are arranged. At its radially outer end, the reflector element has slot-like recesses 7 on.

In 3b is an example of a to the in 4a shown reflector element 1 Bending reflector segment 1 shown. With a connecting element, which passes through one of the recesses 6 the adjacent reflector elements 1 is guided and connects them together, the rotational movement of the reflector segments can be 1 around the axis of rotation 12 limit each other, in particular by 360 ° divided by the number of reflector segments 1 , This facilitates the construction, since so the locking pin 15 only the freedom of rotation between the top reflector segment 3 and the lowermost reflector segment 2 fixed. The recesses 7 limit in the same way the freedom of movement of the reflector segments 1 near the outer outline of the fanned reflector 2a By putting these over fasteners 11 connected to each other. This is how the reflector segments become 1 latched overlapping during fanning and clamping and stopped exactly when stacked together.

4 is a side detail view of the carrier element 8th with a folded reflector. A first arm 17 along the axis of rotation 12 top reflector segment 3 is in the folded state under the second arm 18 of the lowest reflector segment 2 positioned so that the the support element 8th rotatably embracing arms 17 . 18 without dismantling the carrier element 8th their relative position to each other can not lose. Both embracing arms 17 . 18 of the lowest reflector segment 2 are on the carrier element 8th fixed. This allows easy assembly and disassembly by rotation of the support element 8th with one hand, while the top reflector segment 3 is held with the other hand. At this point it should be emphasized once again that the adjacent reflector segments 1 via connecting means 11 permanently connected, both in the fanned out as well as in the imaginary state. Only the top reflector segment 3 and the lowest reflector segment 2 are not connected to each other in the fanned-out state, but they are (with a releasable connection means such as a push button or the like) in the fanned out state when the reflector is formed.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• US 1813102 [0002]
• DE 469116 A [0002, 0012]
• US7014329 [0002]
• US 3286259 A [0005]
• DE 19618434 [0005]
• US Pat. No. 2,806,134 A [0012]
• GB 2272331 A [0012]

Claims (10)

Reflector, between a fanned and a collapsed state about a central, in cross-section circular support member ( 8th ) is fanned around, with a plurality, relative to each other about a common axis of rotation ( 12 ) on the carrier element ( 8th ) movably mounted reflector segments ( 1 ), in the collapsed initial state in the direction of the axis of rotation ( 12 ) are stacked, the stack being a top ( 3 ) and a lowermost reflector segment ( 2 ), and wherein each of the reflector segments ( 1 ) in a fanned-out state in which the reflector segments ( 1 ) form the reflector, forms a reflection surface, characterized in that in the fanned-out state, the reflection surfaces of all the reflector segments forming the reflector ( 1 ) are formed identically and about the axis of rotation ( 12 ) are arranged twisted. Reflector according to claim 1, characterized in that each reflector segment ( 1 ) in the fanned-out state of the reflector in a region forming the reflection surface, with a first edge ( 5 ) under and with a second edge ( 4 ) over the respective adjacent segments. Reflector according to one of claims 1 or 2, characterized in that the reflector segments ( 1 ) each with a first arm ( 17 ) and a second arm ( 18 ) the carrier element ( 8th ) and that a part of the first arm of the uppermost reflector segment ( 3 ) under a part of the second arm of the lowermost reflector segment ( 2 ) is arranged. Reflector according to claim 3, characterized in that the first arm ( 17 ) and the second arm ( 18 ) of a reflector segment ( 1 ) are formed as ring segments of a perpendicular to the circumferential direction completely divided ring. Reflector according to one of claims 3 or 4, characterized in that the first arms ( 17 ) and / or the second arms ( 18 ) at least one recess ( 6 ) and the recesses ( 6 ) lie one above the other in the fanned out state, so that through the recesses ( 6 ) a locking pin ( 15 ) is hindurchsteckbar. Reflector according to claim 5, characterized in that each reflector segment ( 1 ) along the first arm ( 17 ) and the second arm ( 18 ) the carrier element ( 8th ) circumferential, several recesses ( 6 ) separated by an angle of 360 ° divided by the number of reflector segments ( 1 ) are arranged. Reflector according to one of claims 1 to 6, characterized in that one of the reflector segments ( 1 ) at least one point ( 10 ) on the carrier element ( 8th ) is fixed. Reflector according to one of claims 1 to 7, characterized in that each reflector segment ( 1 ) at least one radially outwardly arranged stop device ( 7 ) for an adjacent reflector segment ( 1 ) having the adjacent reflector segment ( 1 ) stops fanning in an overlapping position. Reflector according to one of claims 1 to 8, characterized in that the reflector segments ( 1 ) are inherently rigid elements that can deform elastically under tension. Reflector according to one of the preceding claims, characterized in that the reflector segments ( 1 ) are flat in a collapsed initial state.

Images