JPH0458620B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of Industrial Application) The present invention relates to a processing solution replenishment method for keeping the activity of a processing solution constant for processing photosensitive materials.

(Prior Art) Conventionally, as photosensitive materials on which images are exposed, there are, for example, positive-working and negative-working photosensitive printing plates, and positive-working photosensitive printing plates include a composition containing an O-quinonediazide compound on a support. Some devices are provided with a photosensitive layer having .

By the way, when the photosensitive layer of a positive-working photosensitive printing plate containing an O-quinonediazide compound is exposed to actinic rays through a transparency, the O present in the exposed area is
- Quinonediazide compound changes to carboxylic acid,
The solubility is increased by the alkaline phenomenon liquid, and a positive image is formed when developed.

Furthermore, a negative photosensitive printing plate containing a photosensitive diazo compound on a support may be given solubility in an alkaline developer by, for example, mixing or combining a compound having an acid group such as a carboxylic acid. , those that are designed to produce negative images are often used.

As described above, by developing with an alkaline developer, compounds having carboxylic acid groups dissolved in the developer, other acid components contained in the photosensitive layer, and even carbonic acid dissolved from the air are removed. The gas etc. neutralize and consume the alkaline components in the developer. That is, by developing a photoreceptor having such an alkali-soluble component or a photosensitive material containing a photoreceptor having an alkali-soluble component, the alkaline component in the developer is reduced.

If the activity of the developer decreases due to a decrease in the alkaline component in the developer and the developing ability becomes insufficient, there are two ways to prepare a new developer and replace the entire amount. A method has been used to restore the developing activity of the developer by replenishing the decreased alkaline component.

One method for replenishing this developer is to determine the size of the developer to be used for a certain predetermined period, convert it to the amount of replenishment per unit area, and then replenish the amount at a constant rate each time one photosensitive printing plate is processed. Replenish the amount. Also,
Some products maintain alkaline activity by adding an average required amount at regular intervals to replenish the decreased alkaline content.

(Problem to be solved by the invention) However, in the conventional method, when a large amount of smaller size than the average size is processed in a short time,
If the pre-calculated replenishment amount is refilled every time one sheet is processed, the amount of alkaline components will increase, causing an apparent increase in sensitivity of the photosensitive printing plate, resulting in poor printing durability and poor inkling as a printing plate. It is one of the causes of

On the other hand, when only a small amount of photosensitive printing plate is processed for a long period of time, there is an apparent decrease in sensitivity, and when this is significant, the printing plate becomes smudged, which is one of the causes of smearing on printed matter.

In this way, when developing a large number of photosensitive printing plates with sizes that deviate from the average size, the average replenishment amount is replenished each time one sheet is processed, so the alkaline activity of the developer is maintained appropriately. There will be a change in sensitivity. For this reason, for example, it was necessary to develop the control piece several times a day and manage the alkaline component.

This invention was made against the background of the above circumstances, and even when a large amount of photosensitive material with a size deviating from the average size is to be processed, an appropriate replenisher is automatically replenished and the activity of the processing solution is maintained. Always maintained within the specified tolerance range, with no variation in sensitivity.
It is an object of the present invention to provide a processing solution replenishment method that allows stable development processing at all times.

(Means for Solving the Problem) In order to solve the above-mentioned problem, the present invention detects the film thickness of a non-image area using a film thickness detection means during transportation of a photosensitive material exposed to an image in a processing step. At the same time, the area of the non-image area is measured and integrated by the area detection means, the volume of the non-image area is calculated from the film thickness and area of the non-image area of the photosensitive material, and the area is calculated according to the volume of the non-image area. It is characterized in that it replenishes the amount of replenishing fluid.

(Function) In the present invention, during the transportation of the image-exposed photosensitive material during the development process, the film thickness of the non-image area is selected from the film thickness detection means, and the area of the non-image area is measured from the area detection means. Integrate. Then, the volume of the non-image area is calculated from the film thickness and area of the non-image area of the photosensitive material, and an amount of replenisher corresponding to the volume of the non-image area is replenished.

The replenisher is replenished in an amount corresponding to the volume of the non-image area when the volume of the non-image area reaches a predetermined amount or when a predetermined number of photosensitive materials have been processed.

(Example) Hereinafter, an example of the present invention will be described in detail based on the accompanying drawings.

In the figure, reference numeral 1 denotes a treatment liquid tank, 2 a pre-rinse liquid tank, and 3 a wash gum liquid tank, which are arranged in the main body 4 of the apparatus. Above these, a pair of rollers 5, 6, 7, 8, 9, 10, 11 is used to transport a photosensitive printing plate 12 which is a photosensitive material.
3 is formed.

The photosensitive printing plate 12 is subjected to shower treatment while being conveyed along the conveyance path 13. That is, the liquid injection means 14,
The film is developed with a processing liquid sprayed from a brush roller 15, and a brush roller 16 further removes the diazo compound dissolved in the development to accelerate the development. After squeezing with the roller 7, when passing over the pre-rinsing liquid tank 2, the liquid spraying means 17 sprays the pre-rinsing liquid onto the photosensitive printing plate 12 to clean it. Furthermore, it is squeezed by the roller 9 and sent to the washing gum liquid tank 3.
When passing through this, the liquid spraying means 18 sprays wash gum liquid onto the photosensitive printing plate 12 for treatment.

Between the prerinse section B, which is the next step of the developing section A, and the wash gum section C, there are provided a film thickness detection means for detecting the film thickness of the non-image area of the photosensitive printing plate 12, and an area detection means for measuring the area. A measurement section D consisting of the following is provided.

The measurement section D is composed of a measurement section 19 and a reflection plate 20. The measuring section 19 is shown in FIGS. 2 and 3.
As shown in the figure, it is composed of a cover 21, a light source 22, a reflection sensor 23, and a slit 24. The cover 21 is disposed in a direction perpendicular to the conveying direction of the photosensitive printing plate 12 and is formed wider than the photosensitive printing plate 12 . This cover 2
1 is a light source 22 and a reflective sensor 2 to prevent external light.
Cover 3. For example, a fluorescent lamp is used as the light source 22,
The reflection sensor 23 is composed of, for example, a plurality of light receiving elements. The cover 21 has a slit-shaped opening on the side facing the photosensitive printing plate 12, that is, the lower part, and the light irradiated from the light source 22 is reflected on the photosensitive printing plate 12 being conveyed via the slit 24. The light is received by the reflection sensor 23. This slit 24
is the field diaphragm slit.

The reflection plate 20 speeds up the rise of the detection signal of the reflection sensor 23 and maintains a predetermined voltage level when the photosensitive printing plate 12 is not being conveyed.

This reflection sensor 23 detects the amount of incident light reflected by the photosensitive printing plate 12 and outputs a detection signal related to the area of the non-image area and a detection signal related to the film thickness of the non-image area to the control device 25. do.

In the control device 25, for example, the photosensitive printing plate 12
Since the thickness of the photosensitive layer differs depending on the type of photosensitive layer, the thickness is automatically set according to the type based on the detection signal. Further, in the control device 25, the reflection sensor 23
The detection signal from the sensor is converted into voltage, the area of the non-image area is measured, and the area information is integrated.

The control device 25 integrates this area information, and each time one photosensitive printing plate 12 is processed, the volume of the non-image area is automatically obtained by multiplying the film thickness information and the area information of the non-image area. , this volume information is stored. Then, each time the photosensitive printing plate 12 is processed, the volume information of the non-image area is stored by integrating the volume of the non-image area, and when the integrated volume value reaches a predetermined value, a predetermined amount of replenisher is applied. A drive signal is output to the replenishment device 26 until replenishment. Then, the replenishing device 26 replenishes the processing liquid tank 1 with an amount of replenishing liquid commensurate with the volume of the non-image area.

Next, the operation of this embodiment will be explained.

First, the photosensitive printing plate 12 with an exposed image is developed in the developing section A, and when the photosensitive printing plate 12 is conveyed between the pre-rinse section B and the wash gum section C, which are the next steps, the photosensitive printing plate 12 is developed in the measuring section D. The film thickness detection means outputs a detection signal regarding the film thickness of the non-image area of the photosensitive printing plate 12, and the area detection means outputs a detection signal regarding the area to the control device 25.

The control device 25 integrates the area of the non-image area, and calculates the volume of the non-image area by multiplying the film thickness information and area information of the non-image area each time one photosensitive printing plate 12 is processed. The volume of this non-image area is counted, a plurality of sheets are developed, and when the cumulative volume value of the non-image area reaches a predetermined amount, a drive signal is output to the replenishing device 26.
The replenishing device 26 replenishes the developer tank 2 with replenisher until the amount matches the volume of the non-image area set by the control device 25.

The control device 25 counts the number of photosensitive printing plates 12 to be developed, and when a plurality of plates are processed, the replenishment device 26 replenishes the processing liquid tank 1 with a replenishment amount commensurate with the volume of the non-image area. It's okay.

Alternatively, the reflection sensor 23 of the measurement unit D may detect the reflection intensity of the non-image area of the photosensitive printing plate 12 and output it to the control device 25 to select the type of the photosensitive printing plate 12. Furthermore, the measuring section D may be placed immediately after the developing section A, and the measuring section D is not limited to the reflection sensor 23, and may detect the transmitted light of the photosensitive printing plate 12. Furthermore, the photosensitive material is not limited to the photosensitive printing plate 12 described above;
It can be widely applied to the development of black-and-white and color photosensitive materials.

(Effects of the Invention) As described above, the present invention detects the film thickness of the non-image area of a photosensitive material exposed to an image, calculates the area, calculates the volume of the non-image area, and calculates the volume of the non-image area. Since the amount of replenisher is refilled according to the volume, the elution amount of the photosensitive layer can be read from the volume of the non-image area, and the replenisher can be refilled accurately.
It becomes possible to keep the alkaline activity of the processing liquid constant. Therefore, even when developing a large amount of photosensitive material with a size that deviates from the average size, the activity of the processing solution is always maintained within a predetermined tolerance range, and there is no variation in sensitivity, making it possible to always perform stable development processing.

[Brief explanation of drawings]

FIG. 1 is a cross-sectional view of a photosensitive material processing apparatus to which the present invention is applied, FIG. 2 is a plan view of a measuring section, and FIG. 3 is a cross-sectional view taken from FIG. 1... Processing liquid tank, 2... Pre-rinsing liquid tank, 3...
...Wash gum liquid tank, 4...Device main body, 12...
... Photosensitive printing plate, 19 ... Measurement section, 20 ... Reflection plate, 21 ... Cover, 22 ... Light source, 23
... Reflection sensor, 25 ... Control device, 26 ...
Replenishment device.

Claims (1)

[Claims] 1. During transportation of the image-exposed photosensitive material in the processing step, the film thickness of the non-image area is detected by the film thickness detection means, and the area of the non-image area is measured and integrated by the area detection means, and the area of the non-image area is measured and integrated. Processing solution replenishment for a photosensitive material, characterized in that the volume of the non-image area is calculated from the film thickness and area of the non-image area, and the replenisher is replenished in an amount corresponding to the volume of the non-image area. Method.