DE3007576C2 - Exposure device for photographic enlargers - Google Patents

Description

The invention relates to a lighting device for photographic enlargers according to the Preamble to the main claim.

Photographic enlargers include an optical system in the optical axis between the Light source and the negative through which the rays of the light source that expose the negative are scattered. Illumination systems of enlargers can be divided into three types, which focus on diffuse Relate lighting, semi-diffuse lighting, and converging or direct lighting.

With diffuse lighting, the negative is illuminated with rays that scatter in all directions so that only a few rays fall on the magnifying lens and for the manufacture of a Deduction can be used. Since the negative is illuminated in all directions with the help of rays, prints with soft contrasts result. Minor scratches on the negative will not be visible. The system is particularly suitable for enlarging color negatives.

On the other hand, a semi-diffuse or semi-direct lighting system is essentially used for concentration negative illuminating rays on the magnifying lens must be done with the help of a converging lens. The system requires a great source of light, like an opal lamp, and will

not affected by changes in the focal length of the magnifying lens, so that high-contrast prints be made possible.

This semi-diffuse system is therefore best suited for black and white photos that have sharp contrast require between black and white. Although this system works with color negatives, it has the disadvantage that scratches on the negative are more clearly visible.

The light source for enlargers suitable for color photographs is therefore different much of a light source for black and white photography, while many amateurs commonly use it use a magnifier with semi-diffuse lighting or diffuse lighting, and for economic reasons, so that the desired result cannot always be achieved. DE-AS 10 27 504 discloses an optical copier with a diffuser in the illuminating beam path known, its applicability in the specified sense to an enlargement with diffuse lighting is limited.

The invention is based on the object of providing a lighting device of the generic type create that allows both diffuse and semi-diffuse lighting.

This problem is solved by the characterizing part of the main claim.

According to the invention is an optical system for diffuse lighting and another optical system for semi-diffuse lighting arranged in a housing, which can alternatively be in two different positions in the optical axis of a light source can be brought without the need to add parts, omit or exchange.

The lighting device according to the invention is light in weight, can be manufactured at low cost and compact in size.

In the following preferred Ausführungsbe ¹ games of the invention with reference to the drawing

^{h <} > explained.

F i g. Fig. 1 is an overall perspective view of a photographic enlarger having a first embodiment of a loading according to the invention

lighting device,

F i g. 2 and 3 are perspective representations of the lighting device in different views,

F i g. 4 is a section through the lighting device and the lamp housing in the position for semi-diffuse lighting,

F i g. 5 is a corresponding section in position for diffuse lighting,

F i g. 6 is a section taken along line 6-6 in FIG. 2,

F i g. 7 is a section taken along line 7-7 in FIG. 3, ι ο

Fig. 8 is an overall perspective view a second embodiment of the invention,

F i g. 9 and 10 are perspective views of FIG second embodiment in different viewing directions,

F i g. 11 is a section through the lighting device in the position for semi-diffuse lighting,

F i g. 12 is a corresponding representation for diffuse Lighting,

Fig. 13 is a section through a third embodiment the invention in the position for semi-diffuse lighting,

F i g. 14 is a section corresponding to FIG. 6 and shows a modified spreading tube.

F i g. 1 shows a known photographic enlarging apparatus 4 with a base plate 1, a column 2 and a lamp housing 3, which is perpendicular adjustable on the column. A lighting device 5, which is a first embodiment of the invention is located in the lamp housing 3.

In the following a first embodiment of the invention with reference to Fi g. 2 to 7 are described.

According to FIG. 2 to 5, a housing 6 is provided, which is composed of housing parts 7 and 8, which from heat-resistant, hard synthetic resin, for example urea resin. The housing parts 7 and 8 are to form a tube with a square or rectangular cross-section as shown in Figs composed. The connection is made, for example, with the aid of thin screws 9, as shown in FIG. 7 shows.

According to FIG. 6, the housing 6 accommodates a spreader tube 10 with a right-angled cross-section. The spreader tube 10 consists of synthetic resin, e.g. white, foamed styrene resin with a degree of foaming of 20 to 50, through which an inner surface is achieved that enables diffuse reflection.

The spreading tube 10 has a partition wall 11 which runs obliquely through the interior of the tube and this divided into a first and a second scattering chamber 12 and 19. In the preferred embodiment according to 4 and 5, the partition 11 is made in one piece with the spreading tube 10.

In a manner not shown, the partition wall 11 can be produced separately from the spreading tube 10 and into it can be used and removed therefrom, for example with the aid of in the spreading tube 10 trained guide grooves.

The first scattering chamber 12 is provided with a first light scattering surface 1 ″, which is formed by a surface before the partition 11. An opening or light screen 14 is located in the optical axis of a light source opposite the scattering surface 13, and a first scatter filter 15 is detachably>"> arranged in the housing 6 perpendicular to the Brthn of from the first diffusion surface 13 * reflected light. The first scattering chamber 12 according to the first embodiment has the shape of a prism with a triangular cross section.

A removable converging lens 16, which consists of two lenses, as in F1 g. 4 and 5 is located in the optical axis of the first scatter filter 15 at a distance from this and on its opposite Page. The first light screen 14, the first scattering chamber 12, the first scattering filter 15 and the converging lens 16 serve as a secondary light source and form a first optical system 17.

The converging lens 16 is located in an attachment 18 of the housing 6 which receives the diffusion tube 10. Of the Extension 18 runs at right angles to the axis of the diffusion tube 10. The converging lens 16 and the filter 15 are substantially parallel to the axis of the diffuser 10. In this way, the lighting device forms 5 with the housing 6 and the extension 18 an L-shaped parallelepiped, as shown in FIG. 2 and 3 emerges.

The second scattering chamber 19, that of the other scattering chamber of the scattering tube i0 through the partition 11 is separated, has a greater length than the first scattering chamber 12, as shown in FIG. 4 and 5.

The second scattering chamber 19 has a second light-scattering surface 20 that passes through the other Surface of the partition wall 11 is formed. A second light screen 2t is located in the optical axis of the Light source opposite the second scattering surface 20, as shown in FIG. 5 emerges. A second scatter filter 22 is removable in the housing 6 essentially; at one end of the StreurDhres 10 perpendicular to the web of the light reflected from the second scattering surface 20 is attached. These elements form the second optical The system shown in FIG. 5 is shown.

The housing 6 has in its wall area opposite the first and second light shields 14 and 21 Openings that correspond to the shape and size of the light shields. The light shutters 14 and 21 are covered by removable filters 24 and 25, which are made of milky-white acrylic resin or frosted glass and filter out ultraviolet rays. These filters also provide protection against dust and serve to scatter and control the light from the light source. In the illustrated embodiment the filters 24 and 25 are made of frosted glass.

The diffusion filters 15 and 20 are made of milky-white acrylic resin, frosted glass or the like and are inserted into grooves 26 and 27 which are formed by the outer surface of the spreading tube 10 and the inner surface of the housing 6. Preferably, the filters 15 and 22 have a central region increased thickness.

The lighting device 5 of the first embodiment is in the lamp housing 3 by a Opening made on the top of the lamp housing, usually by means of a of a button 28 to be opened and closed lid 29 is closed, as FIG. 1 shows.

The lamp housing 3 contains a light source 30, a reflector 31 and color setting filter C, mouth Y in those areas in which the light rays are collected by the reflector. The filters C, mouth Y can be displaced in the optical axis with the aid of a button 32 (FIG. 1) via connecting links (not shown).

Like F i g. 4 and 5 show, the lamp housing 3 has an extension 33 which is used to support the Lighting device 5 is used. A bracket 34 (Fig. 1) is at the lower end of the extension 33 for Recording of a negative 35 (FIGS. 4 and 5) in the

optical axis provided. The lamp housing 3 is further provided with a magnifying lens 37 and a Shielding bellows 36 is provided between the magnifying lens and the housing. The magnifying lens 37 is adjustable in the vertical direction with the aid of an adjusting wheel 38 and other devices not shown, as in Fig. 1 is indicated.

When the first optical system 17 is to be used for semi-diffuse illumination, as in FIG F i g. 4, the lid 29 is opened and the lighting device 5 is in the optical Axis between the light source 30 and the negative 35 used so that the projection 18 of the housing 6 in the Approach 33 of the lamp housing 3 enters and the first light screen 14 in the optical axis of the light source lies.

The light from the light source 30 is collected by the reflector 31 and then scattered. If that Light passes through the first light screen 14, further scattering and adjustment takes place through the Filter 24 which is provided in the light shield 14. The light is then emitted from the first scattering surface 13 reflected. The scattered and reflected light in the first chamber 12 hits the first scatter filter 15.

The light passing through the scatter filter 15 serves as a secondary light source for the first optical one System 17. The light strikes the converging lens 16, which collects the light on the converging lens 37. the Converging lens 37 projects the image of the negative 35 onto a magnification mask (not shown) on the Base plate 1 according to FIG. 1.

Thus, the light of the first optical system 17 for illuminating a negative 35 is essentially collected through the converging lens 16 on the magnifying lens 37, as shown in FIG. 4 shows, so that there are high contrasts Enlargements result because the negative is not exposed at an angle to diffuse light.

The arrangement enables an enlarged application range of the first scatter filter 15 as secondary light source. This serves to reduce the ^ UΓ Influence resulting from changes in the focal length of the magnifying lens 37 or the displacement of the Magnifying lens 37 would be assigned for focusing, so that uniform illumination is ensured is. The first scatter filter 15, which has an increased thickness in the central region, is used to correct Irregularities in the lighting.

The above with reference to FIG. 4 described arrangement for semi-diffuse lighting is for a diffuse lighting changed in the following way.

The cover 29 is removed from the lamp housing 3, and the lighting device 5 is taken out of the lamp housing 3 and then rotated so that the light shield 21 of the second optical system 23 lies in the optical axis of the light source and the second scatter filter 22 is on the negative 35 is directed. The housing 6 is inserted into the projection 33 of the lamp housing 3, as shown in FIG. 5 shows. The extension 33 can preferably be provided with a guide for introducing the lighting device 5 be provided.

Since the light source 30 in the lamp housing 3 and the negative 35 are in fixed positions, the length L \ (Fig. 3) of the first optical system 17 from the converging lens 16 to the first light diaphragm 14 is equal to the length L 2 (Fig. 2) of the second optical system 23 from the second scatter filter 22 to the second light screen 21. Preferably, those parts of the housing 6 which are to be inserted into the extension 33 are identical in their external dimensions.

When the second optical system 23 is in the position shown in FIG. 5 is used, the light hits the Light source through the filter 25 on the light shield 21, through which the light is adjusted, to the second Scattering surface 20. The light is scattered again from this scattering surface 20 and into the second scattering chamber 19 reflected. Since the Stred chamber 19 is designed as an elongated tube with a right-angled cross-section, the light for illuminating the scattering filter 22 can be effectively scattered.

The second scatter filter 22, like the corresponding filter of the first optical system 17, is used as a secondary light source for emitting highly diffuse rays for direct illumination of the negative 35. see above that the image of the negative through the magnifying lens 37 on a not shown base on the Base plate 1 is projected. The prints produced are softer in contrast.

For the magnification process described, the lamp housing 3 is preferably displaceable in the vertical direction on the column 2, while the position of the magnifying lens 37 can also be adjusted in the vertical direction with the aid of the handwheel 38. If color adjustment is necessary for color photographs, the filters C, M, Ym can be moved along the optical axis.

F i g. 8 to 12 show a second embodiment of FIG

Invention. Because they are largely identical to the first embodiment, only the essentials are intended Differences are described in more detail.

The scatter filter 15 and the converging lens 16 of the first optical system 17 and the scatter filter 22 of the second optical systems 23 are aligned with one another in the axis of the scattering tube 10 and are opposite one another arranged. The lighting device 5 including the housing 6 has the shape of a right-angled parallelepipeds, as shown in FIG. 9 and 10 is shown. As in the first embodiment, the spreading tube 10 is divided by a partition U, which is preferably arranged at an angle of 45 ° in the spreader tube and first and second Sti eufflächen 13 and

20 has. Opposite the scattering surfaces 13 and 20, there are light shields 14 and 21 in the form of openings in FIG

the spreading tube 10 and corresponding openings in the housing 6.

The lighting device 5 of the second embodiment can be arranged in the vertical direction within a lamp housing 3, as shown in FIG. 8th shows. The second embodiment has the advantage that the lamp housing 3 is compact in the lateral direction can be trained. L) a the lamp housing 3 is displaceable in the vertical direction, prepares the vertical position in the lighting device 5 no trouble if the first and second optical systems 17 and 23 alternate in the optical axis be introduced between the light source 30 and the negative 35, as shown in FIG. 11 and 12 show.

Fig. 13 shows a third embodiment of the invention which is a modification of the second embodiment The difference from the second embodiment is that the Partition 11 is triangular in cross section (hollow or solid) and that the light screen 14 and

21 are provided on the same side. Otherwise it is in agreement with the second embodiment.

The three embodiments described above show some basic features of the invention and allow a number of modifications. For example, the spreading tube 10 can be rectangular, hexagonal or have another cross-section.

The lighting device 5 according to the invention comprises a housing 6 with a scattering tube IO and a partition 11 which divides the interior of the scattering tube 10 into a first scattering chamber 12 and a second scattering chamber 19. The first scattering chamber 12 has a first light scattering surface 13 on the partition wall 11. A first light screen 14 is located in the optical axis of the light source 30 opposite the first scattering surface 13. A first scattering filter 15 is in the path of the light reflected from the first scattering surface 13, and a converging lens 16 is located in the optical axis of the first scatter filter 15 at a distance from this. These parts form the first optical system 17. The second scattering chamber 19 has a scattering surface 20 on the partition 11. A second light shutter 21 is located yi in the optical axis of the light source 30 opposite the second diffusion surface 20. A second scatter filter 22 is located in the path of the light reflected from the second surface scattered light 20. The first and second optical systems 17 and 23 can optionally be introduced into the optical axis of the light source 30 between the light source 30 and the negative 35. This has the following advantages.

By changing the orientation of the lighting device 5 this can be used for semi-diffuse or diffuse lighting, so that optional prints with hard or soft contrast can be produced.

The lighting device 5 can be used for both types of prints in one and the same enlarger can be used without the need for additional parts. The operation is simple and the Manufacturing costs are low. Despite the optional use of two optical systems no changes in weight, making the invention suitable for use in photographic enlargers is suitable in which the lamp housing is movable in a vertical direction and balanced must become.

In addition 5 sheets of drawings

Claims (6)

Patent claims: 1. lighting device for photographic enlargers, with a light source in a lamp housing and a holder for a negative in the optical axis of the light source a scatter tube, at least one scatter filter and at least one converging lens, characterized in that, that the lamp housing (3) em housing (6) with the diffuser tube (10) inside receives that the litter tube (10) through a partition (11) into a first and second litter chamber (12,19) is subdivided so that the first scattering chamber (12) has a first scattering surface (13) on the partition, a first light screen (14) opposite the first scattering surface (13), a first scattering filter (15) across the path of the light reflected from the first scattering surface (13) and the converging lens (16) in the optical axis of the first scatter filter (15) at a distance from the scatter filter that the second Scattering chamber (19) a second scattering surface (20) on the partition (11), a second light screen (21) opposite the second scattering surface (20) and a second scattering filter (22) across the path of the second diffusion surface (20) has reflected light, and that the housing (6) with the The diffuser tube (10) can alternatively be inserted into the lamp housing (3) in two different positions is that optionally the light screen (14) and (21) of the first or second scattering chamber in the optical axis of the light source (30) arrives. 2. Lighting device according to claim 1, characterized in that the first and second Light screen (14, 21) contain filters (24, 25) for filtering out UV rays and that the first and second scatter filter (15, 22) are reinforced in the central area. 3. Exposure device according to claim 1 or 2, characterized in that the first scatter filter (15) and the converging lens (16) and the second scatter filter (22) on the axis of the scatter tube (10) in facing arrangement are aligned and that the housing (6) has the shape of a right-angled Has parallelepipeds. 4. Lighting device according to claim 1, characterized in that the first scatter filter (15) and the converging lens (16) are arranged parallel to the axis of the diffuser tube (10), and that the second scatter filter (22) lies in the axis of the scatter tube, and that the housing (6) has the shape of a Has L-shaped right-angled parallelepiped. 5. Lighting device according to claim 3 or 4, characterized in that the diffuser tube (10) has a rectangular cross-section, and that the second scattering chamber (19) has a greater length than the first scattering chamber (12). 6. Lighting device according to one of claims 1 to 5, characterized in that the Partition wall (11) has light-scattering scattering surfaces (13, 20) on opposite sides and from white, foamed styrene is made in one piece with the spreader tube (10), and that the housing (6) Made of heat-resistant, hard material.