DE3141665A1 - Photographic densitometer - Google Patents

Abstract

A photographic densitometer, in which a photoelectric cell is brought into contact with a material to be measured, such as a developed photographic film, is described. The light from the light source is made to converge by the condenser lens, which is disposed in front of the opening, and the light is directed onto the material, in order to increase significantly the amount of light entering the photoelectric transducer.

Description

- Photographic densitometer

The invention relates to a photographic density meter or a photographic densitometer.

In general, a densitometer or density meter can be used Measure the color density of a photo and the reflection color density of a printed one Object can be roughly sorted or classified into three types: A transparent one Type, a reflection type, and a combined type.

The conventional photographic densitometer consists of one Table and a cantilever arm that extends across the table. On the Surface of the table is mounted an illuminated plate with an opening is provided. In the table under the opening are a heat ray absorption filter also contain a condenser lens and a light source lamp in that order.

At the end of the arm facing the opening is a lens barrel arranged. Also in the arm is a prism or mirror above the lens barrel is provided, and on the side of the prism or mirror is a photoelectric one Tube provided concentrically to the color filter. The lens tube has an opal glass (a milky white, light diffusing glass), which is attached to the front end and also contains a condenser lens.

The light from the light source lamp is passed through the condenser lens, the heat ray absorption filter and the small hole of the opening passed and closed the material, which is arranged on the illuminated plate, blasted or continued. The light which passed through the material is, is further through the opal glass at the front end of the lens barrel, which Condenser lens in the tube, the prism in the arm and in the color filter guided and then occurs into the photoelectric cell, which converts light into voltage or current converts. By the converted voltage and current quantity or its derived Size is possible, the color density and the reflection color density of the material to know.

However, in the conventional photographic densitometer the amount of light that reaches the photographic cell is very small because the parallel rays of light that have passed through the condenser lens, are passed through the small hole of the opening and blasted onto the material and transmitted, diffuse light is also through the opal glass, the condenser lens guided in the lens barrel and the prism of the arm until it finally goes into the photoelectric Cell enters. Therefore, accurate measurement can be made with the conventional device not be made.

When the lamp is used with a high intensity of light, the Compensating for a lack of light, however, can damage the material will.

Especially when semiconductor elements, such as photodiodes or phototransistors, used in the photoelectric converting part of the photoelectric cell, the insufficient amount of light is an obstacle to accurate measurement. To that to converge diffuse light that has been dispersed through the opal glass, various points should be taken into account, such as the rate of diffusion of the opal glass, the shape of the lens barrel and the degree of fineness of the inner Surface of the lens barrel. These factors represent the limitation in manufacturing of the photographic blackening knife.

The object of the invention is therefore the above, in the conventional Devices to avoid disadvantages learned and a photographicXn To provide blackness meter which greatly increases the amount of light which enters the photoelectric cell even when using a conventional lamp thereby enabling an accurate, dense measurement.

The density meter according to the invention makes a light one Manufacture allows, and it can also be made in a compact size.

The photographic densifier according to the invention is thereby characterized in that the material to be measured, such as a developed film the opening is arranged so that the photoelectric cell is in contact with the Material is arranged and that the light from the lamp through the condenser lens is converged or merged, which is arranged in front of the opening, wherein the light through the small hole in the opening, which shines on the material should be let through.

Further advantages, features and possible uses of the present Invention emerge from the following description of a preferred embodiment of the invention in conjunction with the drawings. 1 shows a vertical cross section the main components of a conventional photographic densitometer and Fig. 2 is a vertical () cross-section of the main components of the photographic density meter according to the invention.

Fig. 1 is provided for the purpose of Nergleichs with the invention, The conventional photo blackening knife consists of a table 1 and an arm 2 clamped in on one side or arranged in a cantilevered manner.

On the upper surface of an illuminated plate 3 of the table 1, an opening 7 is fitted. A heat radiation absorption filter is located under the opening 7 6, a condenser lens 5 and a lamp 4 as a light source in this order intended. A fluorescent lamp 17 is also provided in the table 1 for adjustment of the material to be measured to enable and facilitate.

At the end of the arm 2, a lens barrel 8 is provided in such a way that it extends vertically and faces the opening 7. Above the vertical Lens barrel 8 is a reflection prism 11 is provided on the side of a photoelectric Tube 21 is installed. In the arm 2 there is also a cylinder 13 coaxial with it of the photoelectric tube 21 comprising a plurality of evenly spaced Parbfilteml2 has.

The lens barrel 8 has an opal glass 9 at its tip and in its Inside a condenser lens 10.

Fig. 2 is the longitudinal section of the main parts of the photographic Densitometer of this invention.

This photographic density meter consists of a table 1 and a cantilever arm 2 which extends over the table 1.

On the surface of the table 1 an illuminated plate 3 is arranged, which has an opening 7 with a small hole 27, which is almost in a central Part of the same is formed. Under the opening 7 are a condenser lens 14 and a flat reflection mirror 18 is provided in this order. The reflection mirror 18 is in the rack at an angle of 450 attached, on On the reflection side of the mirror 18, a color filter 12 is a heat ray absorption filter 6, a condenser lens 5 and a lamp 4 as a light source in this order intended.

The condenser lens 5 is arranged such that the lamp 4 is on Lens focus is located. The condenser lens 14 is arranged such that if the photoelectric cell 15 is placed in contact with the material S to be measured is, which is located on the illuminated plate 3, the semiconducting photoelectric Cell 16 is arranged at the lens focal point.

The color filter 12 can be changed by turning the KnoSes 20. That is, various types of color filters are attached to the periphery of the disk 22.

The button 20 is at the end of a shaft (not shown) of the disc 22 attached and rotated until the desired color filter 12 is in front of the mirror 18 is coming.

In the table 1 there is also a fluorescent lamp 17 which is only switched on is used to adjust the position of the material S placed on the plate 3, so that that part of the material S to be measured is in alignment to opening 7 is located.

At the front end of the arm 2, a photoelectric cell 15 is vertical movably attached. The photoelectric cell 15 has a front end thereof photoelectric conversion element 16 formed of semiconductors such as e.g. a photodiode or a phototransistor. The arm also has an opal glass 9 the photoelectric conversion element 16. The opal glass can be replaced by another Opal part formed from resin can be replaced. If no opal glass or resin opal part is provided, the one picked up by the photoelectric conversion element 16 is Light amount increased.

The arm 2 is connected to a lever 19 to the photoelectric Raise or lower cell 15. When the lever 19 is down in the dashed line The horizontal position shown in the lines is the photoelectric cell lowered and comes into contact with the surface of the illuminated plate 3 p.

If the photographic density of the material S is to be measured, the lever 19 is first turned up into the position shown with solid lines, to lift the photoelectric cell 15 from the plate 3, and at the same time becomes the fluorescent lamp 17 is illuminated.

Next, the material S is placed on the plate 3 and then adjusted so that the part of the material S to be measured, immediately is in alignment over the small hole 27 of the opening 7. Then the lever 19 lowered to the horizontal position shown with the dashed lines to move the photoelectric cell 15 down, which then with the material S in Touch comes.

The fluorescent lamp 17 is switched off and the lamp 4 is illuminated. There; Light emitted from the lamp 4 passes through the condenser lens 5, the heat radiation absorption filter 6 and the color filter 12 and reaches the reflection; mirror 18, as indicated by the arrow is shown. The light is then reflected vertically upwards by the mirror 18, until it is converged by the condenser lens 14. The converged ray of light goes through the hole 27 of the opening 7 and reaches the material S.

The light that has passed through the material S then passes through the Opal glass 9 through. The transmitted light is immediately converted into the photoelectric Semiconductor conversion element 16 of photoelectric cell 15 inserted where it is in a voltage or a current is converted whose size or whose derived size is shown on the display, not shown.

Because in this invention, the photoelectric cell 15 is in contact with the material placed on the opening 7, the light is emitted from the lamp 4, as stated above, is converged by the condenser lens 14, which is in front of the opening 7 is arranged, and blasted against the material, and there that through the material S transmitted light through the opallate 16 into the photoelectric Cell 15 is introduced is the one entering the photoelectric cell 15 Amount of light about 1000 times greater than that of the conventional one shown in FIG photographic densitometer. That is why it is with the photographic densitometer according to this invention possible very accurate measurements compared to those at the conventional blackening knife.

In addition, since the photographic densitometer according to this invention can use a lamp 4 which emits a smaller amount of light than that the conventional device, there is also the possibility of damaging the material S significantly reduced.

Since this invention also makes it possible to use the lens barrel 8 and to omit the prism 10 used in the conventional devices the accuracy of the measurement will be improved, and the size of the density meter will be improved as a whole becomes small.

Claims (5)

Photographic densitometer priority date: October 23, 1980 in Japan 55-148946 claims photographic density meter, d a d u r c h g e k It is noted that in front of the opening (7) a condenser lens (14) for converging of the light emitted from the light source lamp (4) is arranged and a photoelectric converter (16) in contact with what is to be measured Material (S) is arranged, which is arranged on the opening (7). 2. A photographic density meter according to claim 1, characterized in that that a color filter (12) is provided between the light source lamp (4) and the opening (7) is. 3. Photographic density meter according to claim 1 or 2, characterized characterized in that the photoelectric converter (16) is a milky white light diffuser part (9), such as an opal glass or an opal resin, which is placed immediately before the photoelectric conversion element (16) included in the converter, is attached. 4. Photographic density meter according to one of claims 1 to 3, characterized in that the photoelectric converter (16) is vertically movable is mounted on an arm (2) extending over the table (1). 5. Photographic density meter according to one of claims 1 to 4, characterized in that the opening (7) in the illuminated plate (3) the upper surface of the table (1) is formed and the condenser lens (14) for Converging the light from the light source lamp (4) just below the opening (7) is provided.