WO1998010333A1

WO1998010333A1 - Process and device for recording information on photographic material that can be thermally developed

Info

Publication number: WO1998010333A1
Application number: PCT/EP1997/004792
Authority: WO
Inventors: Thomas Zehetmaier; Jürgen Müller; Friedrich Stumpf; Gerald Halbedl
Original assignee: Agfa-Gevaert Aktiengesellschaft
Priority date: 1996-09-06
Filing date: 1997-09-03
Publication date: 1998-03-12
Also published as: DE69708575D1; DE69708575T2; DE19636235A1

Abstract

A process is disclosed for recording information by means of a recording radiation on photo-sensitive photographic material (7) that can be thermally developed. The material (7) is exposed on an element (3), preferably a drum, generating a latent image. The material (7) is then thermally developed by the same element (3), generating a visible image from the latent one.

Description

Method and apparatus for recording information on thermally developable photographic material

The invention relates to a method and a device for recording information on photosensitive, thermally developable photographic material according to the preambles of claims 1 and 11

A large number of techniques are known for recording information, which are based on different physical and chemical principles. A first group of such methods works on the basis of the so-called thermosubhmation transfer pass from the dye carrier film onto the receiver material color particles and thereby lead to the desired information recording on the receiver material

Such a method and such a device is, for example, from the

DE 38 17 625 C2 known Chemical substances for such image recording methods after thermal sublimation transfer are known, for example, from GB 2 083 726 A. A disadvantage of the thermal sublimation process is that it is technically very complex to record information with a high optical density. Such requirements are particularly required when recording images in medical diagnostic recording procedures. Conventional photographic film, which is exposed to visible light and subsequently carried out in a photographic development process by means of liquid photographic processing baths, has so far largely been used in such recording methods.

Furthermore, so-called "direct thermal" recording methods have become known, in which information - in particular image information - is recorded on heat-sensitive material by directly heating this material point by point. Either so-called thermal print heads can be used, in which microscopic, heated elements mechanically the heat-sensitive material is applied or the heating is effected point by point on the heat-sensitive material by means of infrared heat radiation.For such thermal recording processes, suitable materials and processes are specified, for example, in EP 685 760 A1 and EP 707 978 A1.

Finally, methods are known in which photographic material based on silver salts is first irradiated with recording radiation - in particular with visible light - and thus a latent image is generated. This latent image, which is initially imperceptible to the human eye, is then - similarly to the conventional photographic wet development processes mentioned above - fed to a development process, as a result of which the final image which is perceptible to the human eye and is stable over time is produced. In contrast to the wet development process, the development of the latent image takes place in these so-called "indirect thermal" Procedure, however, by heat. Such methods are advantageous compared to the aforementioned methods because the latent image can be recorded much more precisely with regard to a desired gray level than with the thermal sublimation methods and the direct thermal methods. It is also advantageous with the indirect thermal methods that the Desired optical density, ie the blackening on the recording material, can be generated in two stages and thus with high resolution. On the one hand, density control can be controlled by the amount of light (ie by the intensity of the light and the duration of the irradiation) when the latent image is formed, and on the other hand the density generated in the subsequent thermal development process can be controlled by the amount, ie by the level of the temperature and can be influenced by the process time, the thermal development. The advantage over the conventional, wet-developing photographic processes is that no liquid substances are required.

The industrial applicability of such processes extends from a wide variety of industries, such as the printing industry, the output of information from computers, the output of images in the medical field, and enables both the recording of color images and the recording of black and white images.

Methods, devices and suitable materials for such an indirect thermal method for recording information on photosensitive, thermally developable photographic material are known for example from EP 679 946 A1 and WO 95/30934.

A disadvantage of the known methods and arrangements for thermally developable photographic materials is that they are relatively large, in particular because they have guide and cooling rollers connected upstream and downstream of the respective thermoprocessors

On the other hand, increasingly compact devices are required, particularly in the medical field, because there is usually a lack of space in hospitals and the number of required image recording devices is constantly increasing

It is therefore an object of the invention to provide a method and a device for recording information on thermally developable photographic material, which make it possible to provide compact recording and developing devices

This object is achieved by the technical teaching of claims 1 and 11, respectively

According to the invention, the thermally developable photographic material is both exposed to an element of the recording radiation and thermally developed by this element

In a preferred exemplary embodiment, a drum is used to hold or guide the recording material. The recording material is guided along the surface of the drum, in particular along its outer surface, or even transported by the drum

The recording is preferably carried out with visible light, but it can also be carried out with other radiation, for example with infrared radiation or UV radiation. It creates a latent image in the recording material, which is thermal by supplying heat at a predetermined development temperature is developed. This creates a visible, temporally stable image on the recording material.

In one embodiment, the recording material is exposed to the recording radiation when heated, whereby the latent image is formed. However, the temperature of the recording material should be below the development temperature. The material is then immediately thermally developed, creating a visible image from the latent image.

On the one hand, the invention leads to the fact that more compact devices can be built by using guide elements for the recording material for exposure and development at the same time.

The preheating of the material surprisingly leads to the fact that the thermally developable, photographic material can be exposed for a shorter time than in the already known methods in which the material is exposed to the recording radiation without being heated. It has been shown that the material is more sensitive to the recording radiation when heated.

The recording radiation is preferably generated with a laser, the beam intensity of which is modulated in accordance with the information to be recorded. This modulation can be carried out in a manner known per se using an acousto-optical modulator. The laser radiation can also be modulated directly by modulating the diode current of a laser diode in accordance with the image information.

According to the invention, the recording material is both exposed on a carrier element and thermally developed by this carrier element. The invention thereby makes it possible, in particular, to expose and develop the film on a single drum. The film will applied to the surface of the heated drum and moved along a slow scan recording direction. The exposure takes place between two recording rollers, then the film is transferred at a relatively large wrap angle over the drum or together with the drum to an output area. During beam recording, the temperature of the film is preferably in the range between 80 ° C and 110 ° C. However, this is not a mandatory requirement. The film could also be exposed on a part of the drum that is colder than the other drum parts. It was also possible to expose the film so shortly after it hit the drum that its temperature during recording was still far below the development temperature specified by the film.

To develop the film, it remains firmly connected to the drum surface during a predetermined process time of in particular 10 to 15 seconds. The drum surface is heated to the development process temperature. This temperature is preferably in the range between 110 and 130 ° C. The emulsion side of the film preferably faces away from the drum surface during jet recording.

The optical elements for modulating the recording beam comprise, in a manner known per se, a deflection mirror (polygon or oscillation mirror) or also other deflection units, such as a hologone disk or the like. Optically imaging elements in the beam path of the recording beam are also necessary

Exemplary embodiments of the invention are explained in more detail below with the aid of some figures. Show it:

1 shows an exemplary embodiment of a recording device according to the invention, and FIG. 2 shows an electronic block diagram of the device from FIG. 1.

A laser printer 1 is shown in FIG. It exposes image information with high resolution (eg 5000 x 5000 pixels) on photographic, thermally developable sheet film 7. The film is transparent in the unexposed, developed state and opaque in the exposed, developed state with an achievable maximum density of over 3.5. It contains a light-sensitive silver halide, a light-insensitive silver substance, such as. B. silver behenate, and a reducing agent. In each case a single sheet of the sheet film 7 is removed from a film supply drawer 2 by a suction arrangement 24 from a film supply stack and fed to an exposure and development unit 25, which is preferably thermally insulated. At an opening 40 of the film storage drawer 2 for the removal of the single sheets, a closure 28 is attached, through which the opening 40 can be closed in order to keep vapors and heat away from the film storage stack.

The laser printer 1 comprises film supply and transport units, an electronic control unit 10, optical assemblies 11 and an exposure and development unit 25. Control and setting parameters of the laser printer 1 can be entered via an operating console 17.

The core of the unit 25 is an exposure and development drum 3. The surface 3a of the drum 3 is heated by a heater 6 to a process temperature of approximately 123 ° C. The heater 6 can have electrically operated heating mats, heating wires integrated in the drum surface 3a, inductive heating means or other suitable heating elements. It is preferably with one Control circuit connected so that the process temperature is kept as constant as possible. The drum 3 rotates in the direction of rotation A.

A sheet film 7 to be exposed, which contains an infrared sensitizer, is introduced along a guide plate 27 between the drum 3 and a pressure roller 26. There, the film 7 is pressed onto the surface 3a of the drum and preheated for about 3 seconds until it reaches the area of a first exposure pressure roller 8 due to the drum movement. The film 7 has the emulsion side facing away from the drum surface 3a.

The drum 3 is rotated in direction A by a drive. As a result, the film is moved in a slow scan direction Y from the pressure roller 8 to the pressure roller 9. The exposure of the sheet film 7 takes place between these two rollers 8, 9. For this purpose, a laser beam 12 is modulated in intensity in accordance with the image information to be recorded and directed onto the sheet film 7. The laser beam 12 is generated in a laser 18, which optionally consists of a laser diode, another solid-state laser or a gas laser. The light of the laser beam 12 has a wavelength in the visible range which is adapted to the sensitometric sensitivity of the sheet film 7. In the case of a laser diode, the laser beam 12 is directly passed through

Control of the diode current modulated. In the case of a gas laser as the light source, the laser beam 12 is modulated outside the laser 18 by means of an acousto-optical modulator (AOM) 19. By means of a rotating polygon mirror 21, the laser beam 12 is moved line by line across the sheet film 7 perpendicular to the slow scan direction Y in a fast scan direction X. Lenses 20, 22 shape the laser beam 12 so that it has a spot size of approximately 140 μm in the recording plane of the sheet film 7.

After exposure, the sheet film 7 is thermally developed. The latent image in the sheet film 7 produced by the exposure is thereby developed by heat, so that the exposed areas are blackened permanently. For thermal development, the sheet film 7 is rotated together with the drum 3 in direction A and is thereby printed on the drum from a pressure belt 4. The pressure belt 4 is to be held at a certain tension by means of tensioning rollers 5 with the pressure belt 4 a wrap angle of about 180 ° is generated on the drum 3, by which the process time for thermal development is influenced. By changing the wrap angle, the process time can be changed depending on the recording material used to influence or control the thermal process time, the rotational speed of the drum is wrapped and the rotational speed of the drum are set so that the process time is about 15 seconds. After thermal development, the sheet film 7 is out of the exposure gs- and development unit 25 via cooling rollers 14 in a film outlet nip and from this to a film holder 16. The cooling of the entire device and extraction of exhaust air is carried out by a fan 13. The fan 13 is followed by a filter 29 which filters the exhaust air discharged to the outside

FIG. 2 shows a block diagram of the essential components of the electronic control unit 10

A central data transmission line (BUS) 30 enables data transmission between all electronic components. The image data are taken from an image source (computer, medical diagnostic device, etc.) via an input / output interface. They are processed in the central processing unit 32 in accordance with film and device parameters converted into control pulses for the write control 36 This acts on the laser 18 or on the acousto-optical modulator 19. System data are stored in memories 33 The drive circuit 35 controls all mechanical drives. The heating electronics 34 controls the heating of the drum 3

Exemplary embodiments of the invention have been described. It is clear that other exemplary embodiments can be specified for the person skilled in the art which achieve the effects according to the invention. For example, instead of the outer drum used for development and recording, an inner drum can also be provided in which both the exposure and the Development of the film takes place on the inner surface of the drum. Instead of the pressure tape, a large number of pressure rollers can also be used to press the film onto the heated drum surface Drum held tight

Two sheets of drawings

Claims

Claims:

1. A method for recording information on light-sensitive, thermally developable photographic material (7) by means of a recording radiation, the material (7) being exposed on an element (3), characterized in that the material (7) through this Element (3) is heated.

2. The method according to claim 1, characterized in that the element (3) is a drum.

3. The method according to claim 2, characterized in that the material (7) on the outside of the drum (3) is both exposed and developed.

4. The method according to any one of claims 1-3, characterized in that the material (7) is heated by the element (3) before exposure.

5. The method according to any one of the preceding claims, characterized in that a laser beam (12) is used as the recording beam, the intensity of which is modulated in accordance with the information to be recorded.

6. The method according to any one of the preceding claims, characterized in that the material (7) on the drum (3), in particular by the

Drum (3) is moved along a so-called slow scan recording direction (Y). Method according to one of the preceding claims, characterized in that a film (7) with an infrared sensitizer is used as photographic material and that the film is preheated before it is exposed

Method according to one of the preceding claims, characterized in that the recording radiation is electromagnetic and lies in the wavelength range of visible light and / or in the infrared range

Method according to one of the preceding claims, characterized in that the temperature during the radiation recording is in the range between 80 ° C and 110 ° C and the temperature during the development is in the range between 110 ° C and 130 ° C

Method according to Claim 4, characterized in that the emulsion side of the material (7) faces away from the drum surface (3a) during the jet recording and during the development

Device for recording information on photosensitive, thermally developable photographic material (7) by means of recording radiation with an element (3) for holding or guiding the material (7) during exposure, characterized in that the material (7) for development by the element (3) is heatable

Apparatus according to claim 11, that the element (3) is a drum

Vorπchtung according to claim 12, the material (7) on the outside of the drum (3) is held or guided 14 Device according to one of claims 11 to 13, characterized in that means (3, 6, 26) are provided through which the material (7) can be heated before and / or during the radiation recording

15 Device according to claim 14, characterized in that the means (3, 6, 26) comprise the element (3)

16 Device according to one of claims 9 or 10, characterized in that a laser beam (12) is provided in the visible and / or in the infrared electromagnetic wavelength range as the recording beam

17 Device according to one of claims 13 to 16, characterized by two pressure elements, in particular pressure rollers (8, 9) for pressing the material (7) onto the drum surface (3a), which are arranged so that the recording beam (12) between the two pressure rollers (8, 9) through onto the material (7)

18 Device according to one of claims 1 1 to 17, characterized by a deflection unit (21) which deflects the recording beam (12) in a so-called fast-scan direction (X) over the material (7), a drive (35 ), which moves the material (7) during the exposure in a so-called slow scan direction (Y) and a controller (10) which acts on both the deflection unit (21) and the drive (35)

19 Device according to claims 11 and 18, characterized in that the drive (7) acts on the drum (3)

0 device according to claim 18, characterized in that the drum speed in the slow scan direction (Y) and the wrap angle of the drum (3) are matched to one another and in particular can be controlled by the control (10) that a predetermined development process time for the material (7) is in the range between 3 and 20 seconds

Device according to one of claims 14 to 20, characterized by means (14) for cooling the material (7) after development

Device according to one of claims 11 to 21, characterized in that the material (7) is photographic film

Device according to one of claims 12 to 22, characterized by a band (4) which wraps around the drum (3)