DE8802996U1 - Adjustable lighting device for uniform illumination of an image field - Google Patents

Description

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Pat Ta/Hö - 02.03.88

Adjustable lighting system for uniform illumination

of an image field

The innovation relates to a lighting device for uniformly illuminating an image field according to the preamble of claim 1.

In such lighting devices, it is known to regulate the brightness of the light emitted by a light source by changing the lamp voltage using an electrical circuit. However, regulating the lamp voltage has the enormous disadvantage that it also changes the color temperature of the emitted light. If a photograph is to be taken using the light, this is only possible if color errors are accepted in the subsequent photographic image.

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Pat Ta/Ho - 02.03.88 ,,", ~'l· 3101 .·

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A device that eliminates this error is known from DE-OS 27 57 543. This has a light source, a condenser system, an adjustable diaphragm, various color filters arranged on a carrier and a ring-shaped light guide. Any desired color temperature of the light can be set by moving the color filters arranged on the carrier. To regulate the illuminance, a diaphragm slider is provided, which partially inserts into the almost parallel illumination beam path between the individual condensers.

IC and thus covers most of the beam. The light guide is homogeneously formed on the inside. An unevenly exposed entrance surface of such a light guide is compensated for on the inside by total reflection so that the light exit surface of the light guide has a uniform light intensity distribution. With this lighting device, it is possible to regulate the illuminance without changing the lamp voltage and thus without changing the color temperature of the light. However, since the illuminance regulation by one light value requires the illuminance beam to be covered by the diaphragm slider to half its original area, the displacement path of the diaphragm slider becomes smaller with each stop-down and regulation becomes more and more difficult. Such illuminance regulation is therefore only possible precisely in narrow areas.

A light controller for fiber optic lights with a large number of individual fibers is known from DE-OS 27 45 397. For this purpose, a diaphragm made up of several circular sector surfaces is arranged in the illumination beam path between the lamp and the light entry surface of the fiber optic.

Pat Ta/Ho - 02.03.1

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To regulate the intensity of the light, these circular sector surfaces are moved using a handle, so that the beam of the light beam is cut off asymmetrically in a disadvantageous way. The area of high deflection factors can also only be set imprecisely.

A light flux regulator for controlling the brightness of illumination devices for microscopes is known from DE-OS 27 01 764. This has a carrier and a fixed group of light-permeable channels arranged in the direction of the light. The carrier is arranged so that it can be swiveled along the illumination beam path using a swivel device. However, this device is very large and requires additional space in the illumination beam path of the microscope due to the swivel device.

Finally, an arrangement for the step-by-step shielding of a light-sensitive material is known from DE-PS 690 378. This material is described here as a photocell for an exposure meter, which is covered by an opaque carrier designed as a disk or band. In the case of the band, the carrier has individual fields with a light-permeable hole pattern, with the diameters of the individual hole diaphragms decreasing from field to field. In the case of the disk, the carrier is equipped with individual fields of different grid densities arranged next to one another. Both the carrier designed as a band and the disk can be brought into the active position via fixed positions.

However, the device known from this document for shielding a »transparent material« is only suitable for regulating the brightness of relatively large areas.

Pat Ta/Ho - 02.03.88

It is therefore the task of the present innovation to avoid the disadvantages of the state of the art and to provide a lighting device with a constantly adjustable color temperature, the brightness of which can be precisely regulated over a large range.

This problem is solved by the characterizing part of the claim. Advantageous further developments are the subject of the subclaims.

The drawing shows the innovation in exemplary embodiments. It shows:

Fig. 1: a lighting device according to the innovation; Fig. 2: an opaque band

Carrier;
Fig. 3: an opaque pane designed as a disc

Carrier.

Fig. 4: an opaque carrier with an arrangement of pinholes.

Figure 1 shows an exemplary embodiment of the lighting device, in which a light source 2, a condenser system 3, a device for influencing the color temperature 4, a device for regulating brightness S, a ring-shaped, homogeneous light guide 6 and a collector lens 7 are arranged one after the other in a housing 1. A beam of illumination rays 8 emitted by the light source 2 is bundled onto the light entry surface 9a of the light guide 6 by means of the condenser system 3.

Pat Ta/Ho - 02.03.88

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The device for influencing the color temperature 4 with a color filter 10, a carrier 11 and a handle 12 is arranged between the condenser system 3 and the light guide 6.

By continuously inserting the light beam 8 in the direction of the arrow, it can be partially colored using the filter 10, and the internal reflections in the light guide 6 homogenize this light on the light exit surface 9b of the light guide 6. This allows any desired color temperature of the light to be set, which is particularly necessary when using the light as photographic lighting and for adapting to the sensitization of the various films. The device for controlling the illuminance 5 is also arranged between the device for influencing the color temperature 4 and the light entry surface 9a of the light guide 6. It contains a carrier 13 and a handle 14 and is provided with the locking means 19, shown here as a ball and spring, which, in conjunction with the locking mechanisms 20 of the carrier 13a, ensure precise guidance and a defined position of the carrier 13 in the illumination beam path.

Figure 2 shows an embodiment of a part of the carrier 13 and has an opaque carrier 13a designed as a band. This is divided into 1n individual segments 15 of equal size, with each of these individual segments being assigned a translucent surface 16a-16f. The surfaces 16a-16c are dimensioned in such a way that the surface 16a has a translucent surface portion that is twice as large as the surface 16b and this in turn has a portion that is twice as large as the surface 16c. The translucent surface 16c is followed by a translucent surface 16d consisting of four individually arranged perforated diaphragms 17.

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Pat Ta/Ho - 02.03.88

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The diameters of these individual apertures 17 are each dimensioned the same, so that a reduction in the number of apertures 17 by a factor of 2 results in a halving of the effective light-permeable area. This is done with the areas 16d, 16e and 16f. For a better overview, individual segments with more than four apertures have been omitted in this figure. Since apertures with an effective diameter of 0.25 mm can still be produced economically, individual segments 15 with a number of 64 or 128 apertures are certainly conceivable.

{ ) Figure 3 shows, analogously to Figure 2, an opaque carrier 13b designed as a disk, which is divided into individual segments 15. These each have, analogously to Figure 2, translucent surface portions 18a-18i, the surface portions 18a-18e forming a tapering curved gap and the translucent surface portions 18f-18i each having a number of pinhole diaphragms 17 of the same size arranged next to one another. The surfaces and the diameters of the translucent parts are designed analogously to those in Figure 2. The design of the carrier as a disk and the arrangement in front of the ring-shaped curved light guide 6 (Figure 1) is of equal structural advantage due to the smaller space requirement and the complete accommodation of the carrier in the housing 1.

Figure 4 shows an opaque carrier 13, which is divided into individual segments 15 and can be moved in the direction of the arrow in front of the light entry surface 9a of the light guide 6. An electric motor 21 is assigned to the carrier 13 in the illumination beam path 8 for the continuous adjustment of the carrier 13.

Pat Ta/Ho - 02.03.88 B 3101

In this figure, the individual segments 15 are adapted to the diameter of the light entry surface 9a of the light guide 6 and each have a number of pinholes that increases by a factor of 2. These are evenly distributed over the width of an individual segment 15 and arranged next to one another, whereby the distance between the pinholes 17 is constant within each individual segment 15. By continuously moving the carrier 13 in the illumination beam path 8, a harmonious dimming is achieved, starting from the transparent surface 16c. To change the illuminance by the factor, the carrier 13 must be moved by the same amount in each case. This allows an exact adjustment or change of the illuminance over a large range without additional gear means. The size ratios and distances described here only represent an example and can of course be varied. A disk-shaped design of the carrier is also possible here.

For the sake of completeness, it should be pointed out that instead of a continuously or discontinuously tapering gap, a stepped arrangement of translucent surfaces on a support can also be used. The pinholes of an individual segment can also be placed next to or on top of each other and thus combined to form a matrix of pinholes.

This innovation makes it possible to carry out gradual or continuous brightness control over a large area without affecting the pre-set color temperature of the light.

Pat Ta/Ho -02.03.88 .^ A 3101 U

This is particularly advantageous if this Light photographic films can be exposed. In addition to a

unwanted color shift caused by incorrect V

Color temperature of the light, are also meticulous alignments |

regarding the DIN or ASA sensitivity of the films '

avoided.

Reference number11st

1 Housing 2 Light source 3 Condenser system 4 Device for influencing the colour temperature e Brightness control device I Light guide 1 Collector lens &eegr; Light input area of (6) •b Light exit area of (6) 10 Color filters from (4) 11 Carrier of (4) 12 Handle (4) 13 carrier 13a opaque carrier (tape) 13b opaque carrier (disk) 14 Handling of (5) 15 Individual segments I6a-f translucent surface 17 Pinhole 18a-i translucent surface parts 19 Locking device (ball, spring) to Latching for 19 Electric motor

Claims (9)

: ."B. 2*Qi Pat Ta/Ho - 02.03.88 Adjustable lighting device for uniform illumination \ ■, of an image field Protection claims 1. Lighting device for uniform illumination of an image field, with a light guide that is homogeneously designed inside it, with a filter device for influencing the color temperature and with a device for regulating the illuminance arranged between the light source and the light guide, characterized in that the device for regulating the illuminance (5) has a Q opaque carrier (13) with at least one tapering, light-permeable gap (16a-16c; 18a-18e). Pat Ta/Ho- 02,03,88 ^ _mtB 3101. '', Il TOkt · a · ·♦ « · 2. Lighting device according to claim 1, characterized in that the carrier (13) additionally f has several apertured diaphragms (17). 3. Lighting device according to claim 2, characterized in that individual segments (15) of the Carrier (13) arranged in groups of apertured diaphragms (17) with approximately have equal diameters. 4. Lighting device according to claim 1 to 3, d a - "- characterized in that the device \ 10 for regulating the illuminance (5) has additional locking means (19) and the light-permeable surface portions (16a-f; 18a-i) of the carrier (13) can be brought into the active position by a constantly changed light value factor via locking means (20). 5. Lighting device according to claim 3, characterized in that the number of pinhole diaphragms (17) of adjacent segments (15) varies by a constant factor, wherein the pinhole diaphragms (17) are evenly distributed within a single segment (15). ( _s 6. Lighting device according to claim 5, characterized in that the pinhole diaphragms (17) are arranged next to one another and have a constant distance from one another within a segment (15). 7. Lighting device according to claim 5 or 6, characterized in that an electric motor (21) is assigned to the carrier (13) for continuous adjustment in the illumination beam path (8). Pat Tä/HO - 03.05.88 B 3101 .0 aft.02 996.4 • ■·· ♦··'*· 8. Lighting device according to at least one of the preceding claims, characterized in that the carrier (13) is designed as a band (13a) or disc (13b). 9. Lighting device according to at least one of the preceding claims, characterized in that the device for influencing the color temperature (4) is arranged between the light source (2) and the light guide (6) and has a handle (12) for partially introducing a color filter (10) into the illumination beam path (8).