SE454808B - PHOTOGRAPHIC DENSITOMETER - Google Patents

Description

454 ÅÛS 10 15 20 25 30 35 2 where, however, the amount of light which reaches the photoelectric cell is very small, since the parallel light rays which have passed through the converging lens are guided through the aperture, which is small, and is allowed to hit the material and the diffused light further. guided through the opal glass, the converging lens in the lens mount and the prism in the arm, before finally reaching the photoelectric cell.

Therefore, no accurate measurement can be performed using the conventional device.

However, if a high light intensity lamp is used to compensate for this small amount of light, the material may be damaged. Especially when semiconductor elements, such as photodiodes or phototransistors, are used in the photoelectric conversion part of the photoelectric cell, the insufficient amount of light constitutes an obstacle to accurate measurement. When converging the light diffused by the opal glass, various factors must be taken into account, such as the degree of diffusion of the opal glass, the shape of the lens socket and the degree of surface treatment of the inner surface of the lens socket. These factors constitute a limitation in the manufacture of the photographic densitometer.

An object of the present invention is therefore to overcome the above-mentioned disadvantages of the conventional devices and to provide a photographic densitometer which significantly increases the amount of light introduced into the photoelectric cell, even when a conventional lamp is used, thereby enabling a correct density measurement.

This object is achieved with a photographic densitometer, which has an illuminated plate, in which an aperture is formed and on which a material to be measured is to be applied over the aperture, and a converging lens, which is arranged below the aperture for converging light emitted from a light source lamp, and which densitometer according to the present invention is characterized by a photoelectric transducer which is arranged to be brought into contact with the material to be measured and applied. over the aperture, the converging lens being arranged so that the photoelectric transducer element of the transducer is located in the focal point of the lens when the transducer is in contact with the material.

The invention will now be described in more detail with reference to the accompanying drawings.

Fig. Is a vertical cross-sectional view showing the main components of a conventional photographic densitometer.

Fig. 2 is a vertical cross-sectional view showing the main components of a photographic densitometer according to the present invention.

The conventional photographic densitometer according to Fig. 1, which is shown for comparison purposes, has a table 1 and a cantilever arm 2.

The table 1 has an illuminated plate 3, which is mounted at the upper surface and has an aperture element 7. Under the aperture element 7, in turn, a heat radiation absorbing filter 6, a converging lens 5 and a lamp 4 are arranged as a light source. A fluorescent lamp 17 is arranged in the table 1 to facilitate placement of the material to be measured.

The arm 2 has at its end a lens socket 8, which extends vertically towards the aperture element 7. Above the vertical lens socket 8 is arranged a refraction prism 11, at the side of which a photoelectric tube 21 is installed. In the arm 2 a cylinder 13 is also arranged , which is coaxial with the photoelectric tube 21 and has a plurality of evenly distributed color filters 12. The lens socket 8 has an opal glass 9 at its end and a converging lens 10 inside it.

Fig. 2 is a longitudinal cross-section showing the main components of the photographic densitometer according to the present invention. This photographic densitometer has a table 1 and a cantilever arm 2, which extends over the table 1.

The table 1 has at its upper surface an illuminated plate 3, which has a diaphragm element 7 with a small opening 27, which is formed at an almost central part thereof. Below the aperture element 7, a converging lens 14 and a flat, reflecting mirror 18 are arranged in turn. The reflecting mirror 18 is attached to the frame at a 45 ° angle.

Arranged at the reflecting side of the mirror 18 are in turn arranged a color filter 12, a heat radiation absorbing filter 6, a converging lens 5 and a lamp 4 as a light source.

The converging lens 5 is arranged so that the light source lamp 4 is located in the focal point of the lens. The converging lens 14 is arranged so that the photoelectric semiconductor cell 16 is located in the focal point of the lens, when the photoelectric cell 15 is in contact with the material S to be measured and is applied to the illuminated plate 3.

The color filter 12 can be changed by rotating a knob 20. Several kinds of color filters are attached to the periphery of a disc 22. The color 20 is attached to the end of a shaft (not shown) of the disc 22 and rotated until the desired color filter 12 is advanced. mirror l8.

Arranged in the table 1 is also a fluorescent lamp 17, which is lit only for such control of the position of the material S on the plate 3, that the part of the material S to be measured is brought into line with the aperture element 7.

The arm 2 has a fetal electric one 15, which is vertically movably attached to the front end of the arm. The photoelectric cell 15 has at its front end a photoelectric conversion element 16, which is constituted by semiconductors, such as photodiodes or phototransistors. The arm also has an opal glass 9 in front of the photoelectric conversion element 16. The opal glass can be replaced with another opal element, which is made of resin. If no opal glass or opal element of resin is used, the amount of light received by the photoelectric conversion element 16 is increased.

The arm 2 is provided with a lever 19 for moving the photoelectric cell 15 up and down. When the lever 19 is rotated downwards to the horizontal position shown by dotted lines, the photoelectric cell 15 is lowered into contact with the upper surface of the material S on the illuminated plate 3.

When the photographic density of the material S is to be measured, the lever 19 is first turned upwards to the position shown in solid lines to lift the photoelectric cell 15 from the plate 3 and at the same time the fluorescent lamp 17 is lit.

Thereafter, the material S is applied to the plate 3 and adjusted so that the part of the material S to be measured is applied immediately over the small opening 27 of the aperture element 7.

Thereafter, the lever 19 is lowered to the horizontal position to lower the photoelectric cell 15 into contact with the material S.

The fluorescent lamp 17 goes out, and the lamp 4 lights up. The light emitted by the lamp 4 passes through the converging lens 5, the heat radiation absorbing filter 6 and the color filter 12 and reaches the reflecting mirror 18, as shown by arrows. The light is then reflected by the mirror 18 vertically upwards, until it is converged by the converging lens 14. The converged light passes through the aperture 27 of the aperture element 7 and reaches the material S.

The light passed through the material S further passes through the opal glass 9. The transmitted light is immediately introduced into the photoelectric semiconductor conversion element 16 of the photoelectric cell 15, where it is converted to voltage or current, the value of the voltage or current or a value obtained therefrom being presented in a indicator not shown.

Since, as described above, in the present invention, the photoelectric cell 15 is contacted with the material over the aperture element 7, the light from the lamp 4 is converged by the converging lens 14 in front of the aperture element 7 and is allowed to hit the material, and since the light transmitted through the material S is introduced into the photoelectric cell 15 via the opal glass 16, the amount of light introduced into the photoelectric cell 15 is about 1000 times greater than the corresponding amount of light at the conventional photographic densitometer of Figs.

With the photographic densitometer according to the present invention, it is therefore possible to perform measurements which are very accurate in comparison with the measurements which can be performed with the conventional densitometer.

Since the photographic densitometer according to the present invention can use a lamp 4, which emits a smaller amount of light than the lamp in a conventional device, the risk of the material S being considerably reduced is reduced.

Since the present invention makes it possible to dispense with the lens socket 8 and the prism 10, which are used in conventional devices, the measurement accuracy is improved and the entire size of the densitometer is reduced. f

Claims (4)

10 15 20 25 _, g 454 sos PATENTKRAV A photographic densitometer having an illuminated plate (3) in which an aperture (27) is formed and on which a material (S) to be measured is to be applied over the aperture, and a converging lens (14) , which is arranged below the aperture (27) for converging light emitted from a light source lamp (4), characterized by a photoelectric converter (15), which is arranged to be brought into contact with the material (S) which is to be measured and is arranged over the aperture (27), the converging lens (14) being arranged so that the photoelectric transducer element (16) of the transducer (15) is located in the focal point of the lens when the transducer is in contact with the material. (S). Densitometer according to Claim 1, characterized in that a color filter (12) is arranged between the lamp (4) and the opening (27). Densitometer according to Claim 1 or 2, characterized in that the photoelectric converter (15) has a milky white light-diffusing element (9), such as an opal glass or opal resin, which is mounted immediately below the photoelectric converter element of the converter. (16). Densitometer according to one of Claims 1 to 3, characterized in that the photoelectric transducer (15) is mounted vertically movably on an arm (2) extending over a table (1), at the upper surface of which the illuminated the plate (3) is arranged.