EP0558875A1 - Device for developing one side of a web or sheetlike light-sensitive material - Google Patents

Abstract

The device comprises a metering roll (5) for metered feeding of developer fluid (13) to an applicator roll (4). A contact pressure strip (3), running over at least two spaced rollers (1, 2) arranged substantially parallel to the applicator roll (4) forms a contact surface (11), located between the rollers (1, 2), with the applicator roll (4). The contact surface extends in the axial direction substantially over the entire width of the applicator roll and amounts to at least 1 mm and at most 200 mm in the radial direction. The position of the contact surface along the periphery of the applicator roll is such that a contact pressure component generated by the contact pressure strip is directed against the metering roll. Using the device according to the invention, a developer fluid film thickness which is independent of the speed of rotation is achieved within wide limits on the applicator roll. Since the diazotype material (7) which is to be developed can take up and absorb developer fluid from the applicator roll along a contact zone located beneath the contact surface, the accumulation of developer fluid (36), known to occur at the line where the diazotype material subjected to developer fluid leaves the applicator roll, is very small. Consequently, the copy developed by means of the device according to the invention does not show a wet rim on the diazotype material which is the last to leave the device. <IMAGE>

Description

The present invention relates to a device for the one-sided development of light-sensitive, sheet-like or tape-like material according to the preamble of claim 1.

In particular, it relates to a device for one-sided moistening of light-sensitive diazo material.

Known devices of this type are used, for example, in copiers in which they are intended for the development of diazo copies.

Such a device is shown and described schematically in German published patent application DE 26 00 155. It contains a metering roller made of a metallic core, which is surrounded by a plastic sleeve. The sleeve is provided with fine, helical grooves. The metering roller transfers developer liquid to an applicator roller, which consists of a metallic core and a smooth rubber sleeve. A profile roller, which comprises a metal core and a sleeve made of profiled rings lined up in a row, presses against the application roller. Each of the profiled rings has on the outer surface evenly distributed over the circumference, n-times repeating, outwardly protruding pyramid-shaped tips. Two adjacent rings are rotated by a certain angle.

The aim of the profile roller used in this device is to ensure that the diazo material to be developed is pressed evenly onto the applicator roller the surface of the profile roller should remain as dry as possible in the absence of copy material, so that moistening of the back of a copy to be developed can be avoided.

The German patent application DE 27 46 749 refers to difficulties that arise with the aforementioned profile roller. In the case of very wide copying machines, which are usually used for the production of diazo copies, the forces acting on the copy to be developed are not uniform over the entire length of the gap between the application roller and the profile roller as a result of the sagging of the rollers. In the method described in the mentioned patent application for the development of diazo copies with less than 4.5 cm³ of developer liquid per m² of copy material, even small differences in the pressure in the gap between the application roller and the profile roller affect the generation of developed and undeveloped image areas on the copy. In order to eliminate this problem, it is proposed to press the diazo material against the application roller by means of a profile roller consisting of a plurality of sub-rollers arranged in a row. The sub-rollers are connected to one another in such a way that they can be rotated independently of one another and are radially displaceable relative to one another and can be pressed against the applicator roller so that they can vibrate via a spring element. This is to ensure that forces that are as uniform as possible are achieved along the entire length of the gap between the application roller and the profile roller.

The disadvantage here is that dividing the profile roller into a plurality of sub-rollers arranged in a row with pressure arms that can be moved largely independently of one another and can be preloaded by spring elements is very complex is. Due to the design, there remains a gap between the adjacent sub-rollers for receiving the pressure arm, which leads to an uneven pressure of the material layer against the application roller.

In the aforementioned and other known devices, the developer liquid is applied from the application roller to the diazotype material to be developed in a linear fashion in the gap between the application roller and the profile or pressure roller. The contact time for each surface point to be developed of the diazo material passing through the above-mentioned rollers with the applicator roller is only very short for the absorption of developer liquid. It has been found that far from all of the developer liquid supplied by the applicator roller is released to the diazotype material. The part of the developer liquid which is not released remains on the surface of the application roller. A wedge-shaped build-up of developer fluid occurs on the separation line of the diazo material loaded with developer fluid from the application roller. This is of different sizes, depending on the type of diazo material, the size of the peripheral speed of the application roller and the amount of developer liquid supplied by the application roller. The occurrence of this accumulation of developer liquid is known. It does not have a disruptive effect during the passage of the diazo material through the gap between the application roller and the pressure roller at a constant speed. On the other hand, this developer liquid accumulation is carried along by the end of the diazotype material that runs out of the gap. This edge area is thus excessively exposed to developer liquid, which leads to a wet edge and often to a clearly visible to disturbing dark color this edge leads. The clapping of the picture and the sticking together of individual sheets when storing the copies are also disadvantageous consequences of the wet edge.

Due to the roller system of metering roller and applicator roller rolling on top of one another while developer liquid is sprayed onto the metering roller, a uniform layer of developer liquid is formed on the applicator roller. The layer thickness is essentially dependent on the design of the surface of the metering roller, the surface of the application roller and the pressure of the application roller on the metering roller. It is known that the layer thickness of the application roller is speed-dependent. Due to the roughness of the surfaces of the dosing and application roller, developer liquid is pressed into the nip. With increasing peripheral speed of the rollers, the pressure of the developer liquid sump built up due to the roughness on the roller nip increases and thus has a negative influence on the squeezing behavior of the roller system.

This behavior leads to a kind of "aquaplaning" effect in higher speed ranges. The liquid sump created in the nip between the metering and applicator rollers can no longer be displaced by the rollers rolling off. For the applicator roller, this means that the layer thickness is too great, especially in the middle area. The result of this is that the material to be developed is subjected to an excessive amount of developer liquid in the middle area compared to the edge areas. In addition, the accumulation of developer liquid on the above-mentioned stripping line is increased.

It is the object of the invention to provide a device for the one-sided development of photosensitive sheet or to improve the band-shaped material so that when used in addition to an evenly distributed application of developer fluid, the aforementioned accumulation of developer fluid with the resulting disadvantageous wet edge on the developed copy no longer occurs. The improvement is also intended to enable the application roller to be charged with developer liquid almost at any speed.

This object is achieved according to the invention by the subject matter of patent claim 1. Advantageous developments of the invention are characterized by the features of the dependent claims.

The advantages achieved with the invention according to claim 1 consist in particular in that the material layer is pressed against the application roller with a uniform pressure over the entire surface. A previously unknown, uniform distribution and penetration of the developer liquid into the diazo layer of the material to be developed is surprisingly achieved with the device according to the invention. The fact that the pressure of the diazotype material on the applicator roller is not linear but rather areal over the contact area increases the contact time of each surface point of the diazotype material to be developed compared to the devices mentioned in the introduction. As a result, a larger proportion of the developer liquid supplied by the application roller can be absorbed by the diazo layer. The remaining portion of developer liquid to be removed from the application roller is small. Therefore, there is practically no accumulation of developer liquid on the detachment line of the developed diazo material from the applicator roller. A wet edge at the tapered end the developed copy is barely visible. Experiments have shown that at the current or desired throughput speeds of diazotype material through such devices of 0.5 to 20 m per minute, the contact path of a surface point of diazotype material to be developed on the application roller is advantageously between 1 mm and 200 mm. In the case of smaller contact paths, we approach the known linear gap according to the prior art, where the absorption of developer fluid from the diazo material is too low. If the contact path becomes too large, material handling problems can arise.

When the device is at a standstill, the pressure belt generates a static pressure force against the application roller. When the device is running, the static pressure force is added to a dynamic pressure force which is generated by the pressure band as a result of its inertia. The dynamic pressure force increases with increasing circulation speed of the pressure belt. Because the contact surface is located relative to the gap between the metering roller and the application roller in such a way that a pressure force component generated by the pressure belt and directed against the metering roller or against the gap mentioned is present, the dynamic pressure force prevents the occurrence of the aforementioned "aquaplaning effect". As the speed of rotation of the metering and applicator rollers rolling on one another increases, the component mentioned counteracts the dynamic pressure force, which also increases, counteracts the tendency of the gap between the metering roller and the pressure roller to be enlarged by the developer liquid conveyed. An application of developer liquid to the applicator roller that is almost independent of speed in the peripheral speed range of interest is achieved.

Unevenness or folds in the material layer as well as inaccuracies or a shaft deflection of the application roller are compensated for by the elasticity of the pressure belt. The relatively simple structure saves manufacturing and maintenance costs. If the pressure tape is wetted with developer liquid when the device is idling, this can largely evaporate due to the circulation time, which is advantageously extended in accordance with the tape length of the pressure tape. Subsequent diazo material is not wetted on the back. With the design of the device according to claim 2, almost all of the pressure force generated by the pressure belt acts on the gap between the metering roller and the application roller.

The development according to claim 3 makes it possible to adjust the pre-tension of the pressure belt by changing the distance between the rollers depending on the application.

The development according to claim 4 allows the pressure on the contact surface to be adapted to the requirements.

Especially in combination of claims 3 and 4, it is possible to adapt the size of the contact surface to the requirements by simultaneously adjusting the distance between the rollers and the approach to the applicator roller. Optimal settings for different substrates of the diazo layer, such as paper, tracing paper and film can be made.

With the development according to claim 5, a particularly uniform and slip-free propulsion of the material layer in the device is achieved.

With the development according to claim 6, the assembly and maintenance of the pressure member is further improved. It is easy to pull up or replace the individual narrow band segments. It is also possible to replace a single damaged belt segment without having to replace the entire pressure belt. In addition, the production of narrow, standardized belt segments is cheaper. Pressure tapes for different working widths do not need to be kept in stock, since they can be built up from a corresponding number of tape segments.

If the pressure band has a surface structured with point-like elevations, the elevations being, for example, conical or pyramid-shaped elastic knobs, the pressure band is less wetted by developer liquid when the device is idling. The elastic knobs result in a particularly even pressing of the material layer on the surface of the application roller.

However, it is important to ensure that the size and the spacing of the knobs and their mutual arrangement are coordinated. Optimal results are achieved with further training according to claims 8 and 9. It is assumed that the height of the knobs is about 2 mm. An enlargement of the distances mentioned in the claims would result in markings of the knobs on the copy material. A reduction in the distances mentioned would lead to a higher level of humidification of the material passing through on the back. At very small distances, developer liquid could even be absorbed by the pressure belt due to capillary forces.

The pressure tape is advantageously made of a permanently elastic material, such as an elastomer, rubber, rubber or silicone rubber, in a seamless design produced. The band and the knobs can be designed as an injection molded part.

To prevent the pressure band from running axially, guide devices are used on its outer sides. A running of the pressure belt can arise from the manufacturing tolerances in the manufacture of the rollers, the housing parts or the pressure belt itself or individual belt segments thereof. The course is expressed in such a way that individual band segments or the entire pressure band clamping leave their predetermined position and endeavor to run axially in the direction of one of the ends of the running rollers. The guide devices used in the subject matter of the invention are designed in such a way that there are small guide rollers which roll on the end face of the pressure belt and thus counteract a further axial change in the position of the pressure belt. Due to the rolling process, frictional wear on the pressure belt can be avoided.

In the device according to the invention, a pressure tape made of an elastic material with a certain hardness, which advantageously consists of a plurality of tape segments arranged next to one another, can be adjusted precisely to a desired contact surface and a desired static area by adjusting the distance between the running rollers and the distance between the running rollers and the application roller Pressure force can be set so that an optimal copy quality, as previously mentioned for different materials, is achieved.

Fig. 1

eine schematische Seitenansicht einer erfindungsgemässen Vorrichtung,

Fig. 2

eine vergrösserte Teilansicht der Vorrichtung gemäss der Fig. 1,

Fig. 3

eine perspektivische Ansicht des Andruckorganes mit Andruckband und Auftragwalze, und

Fig. 4

eine perspektivische Ansicht eines Bandsegmentes des Andruckbandes mit einem vergrösserten, die Oberflächenstruktur des Bandsegmentes zeigenden Ausschnitt.

The invention is described in more detail below with reference to figures, for example. Show it

Fig. 1

2 shows a schematic side view of a device according to the invention,

Fig. 2

2 shows an enlarged partial view of the device according to FIG. 1,

Fig. 3

a perspective view of the pressure member with pressure tape and applicator roller, and

Fig. 4

a perspective view of a band segment of the pressure band with an enlarged, the surface structure of the band segment showing cutout.

1 shows a device for one-sided development of light-sensitive material, in particular diazo material, which is used in copiers. Developer liquid 13 is sprayed onto a metering roller 5 arranged underneath via a spray tube 6, which extends over the entire width of the device. The metering roller 5 dispenses the developer liquid by surface contact and distributes it to an application roller 4. The two rollers 5, 4 mentioned press against one another to form a line contact. Due to the rolling of the rollers on one another, the lateral surface of the application roller 4 has a surface which is uniformly exposed to developer liquid on the side of the line contact facing away from the spray tube. Too much developer liquid sprayed onto the metering roller drips into a collecting trough 8 arranged under the metering roller 5. A pressure element is present on part of the cylindrical surface of the application roller 4, which comprises two rollers 1, 2 and a flexible pressure belt 3 guided around it. A contact zone of the pressure belt 3 with the application roller 4 defines a contact surface 11. The surface to be developed Diazotype material 7 is fed in the arrow direction indicated via a feed channel 9 to the contact zone between the pressure belt 3 and the application roller 4. The diazo layer 12 of the diazo material 7 faces the applicator roller 4. The diazotype material 7 to be developed passes through the contact zone and touches the application roller 4 below the contact surface 11. Every small partial area of the diazotype material which is advanced from one end of the contact surface to the other end of the contact surface 11 is metered on the path of the path it has passed through with that on the surface the application roller 4 applied developer liquid. This penetrates along this path into the diazo layer. Then the diazo material 7 is guided out of the device via suitable guide devices (not shown in the figure). Said path, along which each small partial area of the diazotype material to be developed moves below the contact surface 11, is at least 1 mm and at most 200 mm, depending on the diameter of the application roller 4. With a preferred diameter of the application roller 4 of 30 mm, the cylindrical jacket surface wedge of the application roller located below the contact surface has a central angle 32 of approximately 5 ° to approximately 90 °. The contact surface 11 is arranged along the circumference of the application roller 4 such that a pressure force component generated by the pressure belt 3 is directed against the metering roller 5. The position of the contact surface is advantageously such that the central angle 32 mentioned is approximately halved by the extension of a connecting line 19 between the axis 17 of the metering roller 5 and the axis 18 of the application roller 4. In other words, that means that through the roller axes mentioned 17, 18 spanned plane, the contact surface 11, which extends in the axial direction advantageously over the entire width of the applicator roller 4, approximately in the radial direction intersects in an axially extending line of symmetry. The pressure force or pressure force component directed by the pressure belt 3 against the application roller 4 increases the pressure of the application roller 4 on the metering roller 5.

The metering roller 5, the pressure roller 4, the running rollers 1, 2 and the pressure belt 3 move in the directions indicated by the arrows 14, 15, 16. The rollers 1, 2, whose axes run parallel to the axis 18 of the applicator roller 4, are driven by the applicator roller 4 via the pressure belt 3. The speeds of the rollers are adjustable and selected so that a feed speed of the diazotype material, which is carried out between the pressure belt 3 and the application roller 4, can have a speed of 0.5 m per minute to 20 m per minute. In the higher speed range, the developer liquid supplied to the contact line between the rollers 4, 5, in particular in the case of wide rollers, has a tendency to tear open the contact line in the middle roller region by an effect similar to aquaplaning and to form a gap. Such a gap would lead to a stronger application of developer liquid to the outer surface of the application roller in the middle region mentioned and to an uneven development of the diazotype material. In order to prevent this effect, the two rollers 4, 5 must be pressed against each other with increasing speed. With the device according to the invention, this is achieved by the prescribed position of the contact surface. An additional dynamic pressure force of the pressure belt depending on the speed of rotation 3 is added as a result of the inertia of the rotating pressure band to the static pressure force. The total pressure force of the pressure belt 3 on the pressure roller 4 consequently increases with increasing speed. Due to the described position of the contact surface 11, at least one component of the pressure force of the pressure belt 3 also acts on the said contact line. The pressure of the application roller 4 on the metering roller 5 is increased with increasing speed. Consequently, the aquaplaning-like effect just described does not occur in the device according to the invention. The film of developer liquid formed on the side of the contact line facing away from the spray tube on the application roller 4 is formed to be uniformly thin within wide limits regardless of the speed of the application roller.

2, the rollers 1, 2, the pressure belt 3 and the applicator roller 4 are shown enlarged. A diazo sheet to be developed is being advanced between the pressure belt 3 and the pressure roller 4. On the outer surface of the applicator roller 4, a liquid film 33 is present on the supply side of the developer liquid, which has a layer thickness D1, for example. The continuous diazo material is wetted below the contact surface 11. The diazo layer absorbs developer liquid along the distance of 1 mm to 200 mm mentioned. At the end of the contact surface 11, on the detachment line of the wetted diazotype material from the application roller 4, a residual film 34 of developer liquid remains on the outer surface of the application roller 4. This residual film has a layer thickness D2. Another film 35 of developer liquid is present on the surface of the diazo material 7. It has a layer thickness D3. While in devices belonging to the prior art, in which there is only a linear contact of the diazotype material with the application roller 4, it applies that the layer thickness D1 is equal to the sum of the layer thicknesses D2 and D3, the device according to the invention has the sheet-like contact found that the sum of D2 and D3 is less than D1. Part of the developer liquid has already been absorbed by the diazo layer along the contact zone. This has the effect that the known liquid accumulation of developer liquid on the detachment line of the diazotype material 7 from the application roller 4, which is designated in the figure with the reference number 36, is considerably smaller compared to the devices belonging to the prior art. This accumulation of developer fluid has previously resulted in a wet edge of the end of the diazotype material that last emerged from the device.

The pressure of the pressure tape 3 and the size of the contact surface 11 is adjustable. The area can be adjusted by changing the distance between the roller 1 and the roller 2, as indicated by the double arrow 27 in the figure. With this adjustment option, the pretensioning of the pressure belt 3 is adjusted to the respective intended use.

In addition, the roller 1 is designed to be pivotable about the axis of the roller 2. This adjustment option of the roller 1 is indicated by the double arrow 28. In this way, the pressure of the pressure belt 3 against the application roller 4 can be adjusted. In cooperation of the two adjustment options 27, 28, both the size of the contact surface 11 and the pressure can be preselected.

On the side facing the applicator roller 4 The pressure band is preferably structured with punctiform elevations. As already mentioned, the pressure band 3, which, as indicated in FIG. 3, is advantageously designed with band segments 20 arranged next to one another, consists of a permanently elastic material, preferably in a seamless design. Each individual band segment 20 can be produced as an injection molded part with great dimensional stability and inexpensively.

A tape guide device 10 is provided on each side of the pressure tape 3. This acts on the strand 26 of the pressure belt 3 facing away from the contact surface 11. The belt guide device 10 has a support element 29 on which two guide rollers 30, 31, preferably made of plastic, are rotatably mounted. The guide rollers of the two tape guide devices 10 each roll on the lateral edge of the said run of the pressure tape. This ensures wear-free tape guidance. The tape guide device 10 prevents the pressure tape from running axially.

A running up of the individual band segments onto neighboring band segments can be avoided by the thickness of the band segments as well as by the hardness of the material. These two sizes must be coordinated. The thinner the band segment, the greater its hardness.

4, a single band segment 20 is shown. It has been manufactured as an annular part that can be stretched over the two rollers 1, 2. Since the belt segment stretched into an oval always has the tendency to return to its original, circular state, an additional pressing force of the stretched belt segment against the pressure roller is generated. The one on the outside of the band segment 20 with elevations 21 structured surface is visible in the figure in sections. The elevations 21 can be pyramid-shaped or conical knobs made of the same elastic material from which the band segment is made. The height of the elevations is preferably about 2 mm. Depending on the choice of material, however, it can also be higher or less high. In the radial direction, the individual knobs 21 of the pressure band have a mutual distance 24 of 0.5 mm to 4 mm, preferably of 2 mm to 3 mm. The knobs 21 form radially next to each other, adjoining dimpled sheets 23. The width of each of the dimpled sheets 23 is designated by 25 and can preferably correspond to the aforementioned distance 24. Each of the dimpled sheets is radially offset from the adjacent dimpled sheet by an amount that is smaller than said distance 25. The radial offset is preferably such that the same knob position is always achieved again after three knobbed tracks.

As already mentioned above, it is important that the knob structure, the material of the band segment, the size of the contact surface and the pressure force of the pressure band are coordinated in the manner outlined. This enables the diazotype material to be developed with a level of homogeneity not previously achieved.

Claims (11)

Device for one-sided development of light-sensitive, sheet or ribbon-shaped material, in particular for developing diazotype material (7), with means (9) for feeding and transporting the material, with a metering roller (5) for metered supply of developer liquid (13) to one Applicator roller (4) and with an organ (1, 2, 3) for pressing the material (7) against the applicator roller (4), characterized in that the organ (1, 2, 3) for pressing the material (7) against the application roller (4) is a pressure belt (3) which is guided over at least two spaced-apart running rollers (1, 2) arranged essentially parallel to the application roller (4), that the pressure belt (3) is a contact surface located between the running rollers (1, 2) (11) to the application roller (4) that the contact surface (11) extends in the axial direction substantially over the entire width of the application roller (4) and is at least 1 mm and at most 200 mm in the radial direction, j However, it is dimensioned such that the diazo material (7) passing through for the development between the pressure belt (3) and the application roller (4) takes developer liquid (13) from the application roller (4) along a contact zone located below the contact surface (11) and into it Can take diazo layer (12) and that due to the position of the contact surface (11) along the circumference of the application roller (4) a pressure force component generated by the pressure belt (3) is directed against the metering roller (5). Device according to Claim 1, characterized in that a plane (19) spanned by the axes (17, 18) of the metering roller (5) and the applicator roller (4) intersects the contact surface (11) approximately along an axially extending line of symmetry. Apparatus according to claim 1 or 2, characterized in that at least one of the rollers (1, 2) is adjustable for changing the roller spacing. Device according to one of claims 1 to 3, characterized in that the distance between at least one of the rollers (1, 2) and the applicator roller (4) is adjustable. Device according to one of claims 1 to 4, characterized in that the running rollers (1, 2) are driven by the application roller (4) via the pressure belt (3). Device according to one of claims 1 to 5, characterized in that the pressure band (3) is divided into a plurality of axially adjacent band segments (20). Device according to one of claims 1 to 6, characterized in that the pressure belt (3) on the side facing the pressure roller (4) with a conical or pyramid-shaped elastic knobs (21) has a structured surface. Apparatus according to claim 7, characterized in that the knobs (21) of the pressure band (3) have a mutual distance (25) in the radial direction of 0.5 mm to 4 mm, preferably 2 mm to 3 mm, and on radially extending, adjoining dimpled sheets (23) are arranged. Apparatus according to claim 8, characterized in that the width (26) of each of the studded sheets (23) is approximately equal to the mutual distance (25) of the studs and that each of the studded sheets to the adjacent studded sheet by an amount which is smaller than the said distance ( 25) is arranged radially offset. Device according to one of claims 1 to 9, characterized in that the pressure band (3) is made of an elastic material, preferably seamless. Device according to one of claims 1 to 10, characterized in that at least one band guiding device (10) acting on the lateral edge of the pressure band in the region of the outer sides of the pressure band (3) on the run (26) facing away from the contact surface (11) for preventing an axial course of the pressure belt (3) is present.

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