[0001] This invention relates to the processing of radiation sensitive devices comprising
a radiation sensitive coating on a substrate and is concerned with the processing
of such devices using an apparatus comprising a container for developer liquid and
a means for contacting the devices with the liquid.
[0002] Such radiation sensitive devices are used in the production of, for example, printing
plates, in particular lithographic printing plates; printed circuits; and integrated
circuits. Radiation sensitive devices for use in the production of lithographic printing
plates usually consist of a substrate in the form of a metallic support sheet, which
is mechanically and/or chemically treated to provide a suitable working surface and
which carries the radiation sensitive coating. In use, the device is image-wise exposed
to actinic radiation using either a negative or a positive transparency of an appropriate
subject. The effect of actinic radiation is to alter the solubility of the radiation-sensitive
coating. The image-wise exposed device is then processed. The processing step involves
contacting the image-wise exposed device with a developer liquid to selectively dissolve
unwanted areas of coating from the support sheet to leave an image constituted by
the areas of the coating remaining on the support sheet. Other types of printing plates
and printed and integrated circuits are produced in a similar manner.
[0003] The negative or positive transparency commonly comprises a silver halide layer which
forms and provides a line image or a half-tone image or a continuous tone image, or
any combination of such images. Of the numerous radiation sensitive coatings that
can be used for the devices, poly(vinyl cinnamate) and diazo resins are typical of
those that can be used in conjunction with negative transparencies, whilst dichromated
gum and quinone diazides optionally in combination with novolak resins are representative
of those that can be used when exposure is carried out beneath a suitable positive
transparency.
[0004] The precise processing routine, and the developer liquids used, depend on the solubility
and chemical characteristics of the radiation sensitive coating being processed. Whilst
the processing may be done manually it is increasingly being carried out automatically
using apparatus such as those described in British Patent Specifications No.1,253,026
and No.1,299,864 and United States Patent Specifications No.3,552,293 and No.4,001,854.
[0005] Some radiation sensitive coating/developer combinations aresignificantly affected
by the developer temperature and variation from the predetermined temperature results
in incorrect development and unsatisfactory reproduction of the transparency. As is
well known, a measure of the ability of a radiation sensitive plate to reproduce a
transparency may be obtained by exposing the plate through an exposure guide known
as a "grey-scale" or "step-wedge". A typical example of such an exposure guide consists
of a number of steps of increasing optical density, the first step being clear. The
actual steps that are reproduced on the plate depend on the particular radiation sensitive
coating/developer conditions. However it is desirable that for a given set of conditions
the reproduction of the step-wedge is always the same. Variation in the temperature
of the developer could prevent such results being obtained.
[0006] It is an object of this invention to provide an apparatus for processing image-wise
exposed radiation sensitive devices which compensates for any changes in the operating
temperature of the developing liquid.
[0007] Because of the variations in the processing routines, there are problems in providing
apparatus capable of processing different radiation sensitive devices. Thus, a processing
apparatus with a developer bath length of, for example, 12 inches (about 31 cm) will
have an optimum plate speed of 35 inches (about 90 cm) per minute when used for developing
a negative working radiation sensitive plate with an organic solvent developer and
an optimum plate speed of 20 inches (about 51 cm) per minute when used for developing
a positive working radiation-sensitive plate with an alkaline developer.
[0008] It has been found that if an image-wise exposed positive working radiation sensitive
device is processed by including the step of giving it a brief overall uniform exposure
to actinic radiation before or during the development, the development time can be
decreased. When this exposure is given manually, it is difficult to obtain predictable
and repeatable results because the exposure conditions are difficult to control. This
problem can be solved by giving the device an overall exposure to relatively less
intense actinic radiation for a relatively longer time whilst the plate moves along
a path past the source of radiation. However, it has been found that the degree to
which a given device needs to be subjected to an overall exposure in order to obtain
a given result is dependent on the temperature of the developer liquid.
[0009] It is another object of the invention to provide an apparatus for processing an image-wise
exposed radiation sensitive device by giving the device an overall exposure, before
or during development, which overall exposure is controlled in dependence on the temperature
of the developer liquid.
[0010] According to the present invention there is provided an apparatus for processing
an image-wise exposed radiation sensitive device which apparatus comprises
(i) a container for developer liquid,
(ii) a means of contacting the device with the developer liquid,
(iii) a temperature sensitive member for sensing the temperature of the developer
liquid and for producing an output signal in dependence on that temperature, and
(iv) a means for controlling the processing of the device in a manner dependent on
said output signal whereby the degree to which the device is processed is dependent
on the temperature of the developer liquid.
[0011] In one embodiment the apparatus includes a means of moving the device with respect
to the developer liquid, the output signal being used to control a motor for driving
the device moving means. In one form of this embodiment, the device moving means comprises
a pair of rollers for feeding the device at an appropriate speed along a path through
the developer liquid. In an alternative form, the device moving means comprises a
mechanism for dipping the device into the developer liquid in the container and for
withdrawing the same after an appropriate time interval. In either case the residence
time of the device in the apparatus is dependent upon the output signal i.e. upon
the temperature of the developer liquid. In an alternative embodiment the developer
liquid is fed to the device for a period of time dependent on the output signal. In
this case also the device and the developer liquid are in contact for a time dependent
on the temperature of the developer liquid. Alternatively or additionally the output
signal may be used to control a motor for driving a roller arranged to agitate the
developer liquid in contact with the device so that the speed of rotation of the roller
is dependent upon the output signal i.e. upon the developer liquid temperature.
[0012] In a further embodiment, the apparatus additionally includes a source of actinic
radiation arranged in or adjacent to the apparatus so that the processing also involves
the step of subjecting the device to an overall uniform exposure prior to or during
its contact with developer liquid. In this case, the degree to which the device is
subjected to radiation from said source may be controlled in dependence on said output
signal. This may conveniently be effected by interposing a variable aperture between
the source and the path and regulating the size of the aperture in dependence on said
output signal.
[0013] Positive working radiation-sensitive devices typified by quinone diazide sensitised
devices are used in the technique known as 'screenless lithography' i.e. the technique
in which the device is exposed directly through a continuous tone master, without
the use of the conventional half tone screen. Processing the plate by subjecting it
to an overall exposure before developing increases the range of tones that can be
obtained. Again, however, it is difficult to obtain predictable and repeatable results
when this is done manually. An apparatus of the invention including a source of actinic
radiation as aforesaid can be used to process these plates, variations in the tonal
range being produced by varying the duration of the intensity of the overall exposure.
Alternatively if it is desired to keep these parameters constant, the tonal range
can be varied by altering the speed at which the plates pass the radiation source.
Clearly, variation of exposure duration and intensity and variation of plate speed
can be combined to give better control of the tonal range.
[0014] For a better understanding of the invention and to show how the same may be carried
into effect, reference will now be made, by way of example, to the accompanying drawings,
in which:-
Figure 1 is a schematic diagram of an apparatus in accordance with the present invention;
Figure 2 is a block diagram of-the control circuit of the apparatus of Figure 1;
Figure 3 is a circuit diagram of a part of the control circuit shown in Figure 2,
Figure 4 is a schematic diagram of another apparatus in accordance with the present
invention,
Figure 5 is a schematic diagram of a further apparatus in accordance with the present
invention,
Figure 6 is a schematic diagram of yet another apparatus in accordance with the present
invention,
Figure 7a shows one embodiment of a part of the apparatus of Figure 6,
Figure 7b shows another embodiment of the part shown in Figure 7a,and
Figure 8 is a schematic diagram of a further apparatus in accordance with the present
invention.
[0015] Referring to Figure 1 the apparatus comprises a tank 1 for containing developer liquid,
a pair of rubber covered input rollers 2 and 2a, a pair of rubber covered output rollers
3 and 3a and a d.c. electric motor 4 connected to drive the roller 2. Roller 2a is
driven by contact with roller 2. (The rollers 3, 3a may also be driven from the motor
4 if desired). A temperature sensitive member in the form of a probe 5 containing
a thermistor is mounted in the tank 1 so as to lie in the developer.
[0016] Referring to Figure 2, the electrical control circuit consists of a constant voltage
source 9 in the form of an integrated circuit voltage regulator, a temperature voltage
converter 10 incorporating the thermistor, and a servodevice 11 in the form of a d.c.
thyristor controller, the output of which controls the speed of the motor 4.
[0017] As shown in Figure 3, the regulated voltage from the source 9 is fed through the
thermistor 12 to a pair of d.c. amplifiers 13 and 14. Variation in the temperature
of the thermistor 12 causes a change in its resistance which in turn produces a change
in the input voltage to the amplifier 13. The output of the amplifier 14 is connected
to the servo device 11. A variable resistor 15 is provided to vary the gain of the
amplifier 13.
[0018] In use, an image-wise exposed radiation sensitive plate is fed into the input rollers
2 and 2a which move the same along path 6 through the apparatus and then out of the
apparatus via output rollers 3 and 3a. During its passage along the path 6, the plate
is submerged in the developer liquid in tank 1 whereby the more soluble areas of the
image-wise exposed radiation sensitive coating of the plate are selectively removed.
The residence time of the plate in the apparatus is automatically controlled in dependence
on the temperature of the developer liquid. The higher the temperature of the developer
liquid as sensed by the probe 5. the faster is the speed of the motor 4 and hence
the shorter is the residence time.
[0019] Clearly, the temperature compensation that will be suitable for one combination of
radiation sensitive coating and developer liquid will not necessarily be suitable
for another. Suitable variation of the change in motor speed with temperature may
be obtained by adjusting the potentiometer 15. Further, in the case of a given radiation
sensitive coating/developer liquid combination the potentiometer 15 may be adjusted
to vary the contrast of the developed plate. Moreover, the setting of thepotentiometer
15 may be varied to allow for an alteration in the activity of the developer liquid
as a result of partial exhaustion.
[0020] Referring to Figure 4, the apparatus includes a pair of rubber covered input rollers
20 and 20a, a pair of rubber covered output rollers 30 and 30a, and a d.c. electric
motor 40 for driving the rollers 20 and 20a. The apparatus includes a separate reservoir
21 for developer liquid and a pump 25 for delivering developer liquid to a spray bar
26 located between a pair of plush covered rollers 23 and 23a driven by a separate
motor 24. A planar member 22 is located under the rollers 23 and 23a and bar 26 and
a catch tray 27 is provided to return developer liquid to the reservoir 21. The apparatus
includes a temperature sensitive probe 28 similar to that of the apparatus of Figure
1 and this is preferably located in the reservoir 21 as shown. The apparatus also
includes an electrical control circuit of the type shown in Figures 2 and 3 and the
output from the servo device of the circuit is fed to motor 40 and/or motor 24.
[0021] In use, an image-wise exposed radiation sensitive plate is fed face upwards along
a path between the input rollers 20 and 20a, between the rollers 23 and 23a and the
member 22, and then between the output rollers 30 and 30a. The exposed radiation sensitive
coating of the plate is contacted by the rollers 23 and 23a and development is carried
out by a combined scrubbing and solvent action. The arrangement is such that with
increased developer liquid temperature, (i) motor 40 (and hence rollers 20 and 20a)
rotate faster and hence the residence time of the plate in the apparatus is shorter
and (ii) motor 24 (and hence rollers 23 and 23a) rotate slower and hence the developer
liquid on the exposed coating is subjected to a less severe agitation. The degree
to which the plate is processed is thus dependent on the temperature of the developer
liquid and, as in the case of the apparatus of Figures 1 to 3, this relationship can
be adjusted as desired.
[0022] Referring to Figure 5 the apparatus comprises a tank 41 forcontaining the developer
liquid and a pair of rubber covered input rollers 42 and 42a and a pair of rubber
covered output rollers 43 and 43a defining a path 46 through the apparatus. An electric
motor 44 is included to drive the roller 42, roller 42a being frictionally driven
by roller 42. The rollers 43 and 43a may also be driven from the motor 44 if desired.
The apparatus also includes a means of subjecting radiation sensitive plates passing
along the path 46 to an overall uniform exposure to actinic radiation. Preferably,
this is in the form of a plurality of sources of actinic radiation and/or one or more
moveable sources so that the apparatus can be used to process plates requiring to
be subjected to an overall exposure from different positions. Examples of suitable
positions are denoted by references 45a to 45e. The positions 45d and 45e are usable
when the plate is being processed face down. In the case of position 45e the tank
must, of course, be translucent. A means (not shown) is provided to sense the presence
of a plate along said path 46 and to actuate the source of actinic radiation when
the plate reaches a position along the path 46 at which it can receive radiation from
the source. (Alternatively, the source may be actuated manually when the plate reaches
a suitable position along the path). A temperature sensitive member in the form of
a probe 31 containing a thermistor is mounted in the tank 41 so as to lie in the developer
liquid. The thermistor forms part of a control circuit of the type described with
reference to Figures 2 and 3 and is operably connected to the motor 44 so that the
speed of the motor increases (and hence the residence time of the plate decreases)
with increase in developer temperature. Alternatively, or additionally, the thermistor
may be operably connected to a means of regulating a variable aperture (e.g. in the
form of a slit of adjustable width forming, for example, a part of a shutter mechanism)
located between the radiation source and the plate path.
[0023] In use, an image-wise exposed radiation sensitive plate is fed into the input rollers
42 and 42a which move the same along the path 46 through the apparatus and then out
of the apparatus via output rollers 43 and 43a. During its passage along the path
46, the plate is submerged in the developer liquid in the tank 41 whereby the more
soluble areas of the image wise exposed radiation sensitive coating of the plate are
selectively removed. The residence time of the plate is controlled in dependence on
the developer liquid temperature. As the plate passes the source of actinic radiation
the whole surface of the plate is exposed. In the case where the apparatus includes
a variable aperture as above described, this too is regulated in dependence on the
temperature of the developer liquid in order to give the plate a desired overall exposure
dependent on said temperature.
[0024] The source of actinic radiation may be of any suitable type, for example a mercury
halide lamp, a pulsed xenon lamp or an ultra violet lamp. Further, in the case where
the apparatus is such as to give the plate an overall exposure dependent on the developer
liquid temperature, it may include one or more filters and a means of interposing
the same between the plate path and the source as appropriate in dependence on said
temperature so that the amount of radiation reaching the plate during the overall
exposure is dependent on the temperature of the developer liquid.
[0025] Referring now to Figure 6 parts corresponding to parts of the apparatus of Figure
5 are denoted by like reference numerals. The apparatus is identical to that of Figure
5 except that the probe 31 is not operably connected to motor 44. In this case the
probe 31 is operably connected to a means 50 of regulating the amount of radiation
reaching the plate from the radiation source (45a) so that the degree to which the
plate is given a uniform overall exposure as it passes through the apparatus is controlled
in dependence on the developer liquid temperature.
[0026] Means 50 is shown schematically in Figure 6. It may, for example, be in the form
of a controllable aperture located between the source and the plate path. Such an
arrangement is illustrated in Figure 7a. Referring to this Figure, the source includes
a tubular lamp 55 located within a casing 56 having a slit arranged transversely with
respect to the path such that radiation from the source can impinge on plates passing
along the plate path. Shutters 57 are mounted at the sides of the slit and co-operate
with the slit to provide a variable aperture for the source. The shutters are displaceable
towards one another so as to reduce the size of the aperture (and hence reduce the
amount of radiation reaching the path) or away from one another so as to increase
the size of the aperture (and hence increase the amount of radiation reaching the
path). Each shutter 57 carries a rack which is engaged by a pinion 58 driven by a
motor (not shown) so as to displace the shutters 57. The motor is operably connected
to the probe immersed in the developer liquid in a manner such that the degree to
which the pinion is rotated (andlence the size of the aperture)is dependent on the
output signal generated by the probe and its associated circuitry. In this way, the
amount of radiation to which the plates are subjected is determined by the developer
liquid temperature.
[0027] In an alternative embodiment the means 50 may be in the form of a plurality of filters
arranged to be selectively interposed between the source and the plate path. Such
an arrangement is illustrated in Figure 7b where parts corresponding to parts of Figure
7a are denoted by like reference numerals. The slit is closed by means of a displaceable
radiation filter 59 which comprises adjacent portions of differing radiation transmittance.
The filter 59 carries a rack which is engaged by the pinion 58. Rotation of the pinion
causes the filter 59 to be displaced across the slit so that one or other of its portions
is interposed between the source and the path. The amount of radiation reaching the
path is dependent on which of these portions is interposed between the source and
the path. As in the case of Figure 7a the degree to which the pinion is rotated (and
hence which portion is so interposed in any given case) is dependent on the output
signal generated by the probe and its associated circuitry and thus the amount of
radiation to which the plates are subjected is determined by the developer temperature.
[0028] Referring now to Figure 8, parts corresponding to parts of Figure 4 are denoted by
like reference numerals. In this embodiment, the image-wise exposed radiation sensitive
plate is placed on the member 22 face upwards. (The plate may be placed in position
manually or automatically). Developer liquid is sprayed onto the plate from a plurality
of spray bars 26' arranged so that the entire surface of the stationary plate is contacted
with developer liquid. The liquid line carrying developer liquid from the reservoir
21 to the spray bars 26' includes a valve 60 actuated by a timer 61 operably connected
to the output signal generated by the probe 28 and its associated circuitry. The arrangement
is such that the period of time during which developer liquid issues from the spray
bars 26' is dependent on the developer liquid temperature.
[0029] The following Examples illustrate the invention.
Example 1
[0030] A positive working presensitised plate consisting of a grained and anodised aluminium
substrate coated with a radiation sensitive mixture of a naphthoquinone diazide sulphonic
acid ester and a novolak resin, was exposed beneath a half-tone positive accompanied
by a continuous-tone step-wedge to light emitted from a mercury halide source for
2 minutes. It was then processed using the apparatus of Figures 1 to 3 with the tank
filled with a developer liquid comprising a 6% aqueous solution of sodium metasilicate
at a temperature of 20°C. At this temperature, the motor drove the input rollers at
a speed which was such that the plate was immersed in the developer liquid for two
minutes. The image of the processed plate contained eight "grey" steps of the control
step-wedge.
[0031] The example was repeated with the developer liquid at 25
0C. At this temperature, the motor drove the input rollers at an increased speed under
the control of the temperature sensitive member such that the plate was immersed for
one minute. The processed image included the same eight 'grey' steps and no difference
could be detected between the reproduction of the positives when compared with that
previously obtained at 20°C.
[0032] For comparison, the example was repeated with the temperature of the developer liquid
at 25
0C but without temperature compensation. The plate was thus immersed for two minutes.
A severely over-developed image containing more "grey" steps and no "solid"steps was
obtained. The reproduction of the positives was bad and unacceptable.
Example 2
[0033] A deep-etch plate consisting of an anodised substrate having a radiation sensitive
coating based on dichromated gum arabic was exposed through a line and half-tone positive
master and a continuous tone step-wedge.
[0034] The exposed plate was fed into the apparatus of Figuresl to 3 with the tank containing
a 50% w/v aqueous solution of calcium chloride at 15°C as developer liquid. The apparatus
was adjusted so that the plate was developed for 6 minutes.
[0035] The plate was finally washed with anhydrous alcohol to remove all traces of the developer
liquid. Examination showed that a satisfactory resist had been obtained and that the
step-wedge had been developed until step number 10 had been cleared.
[0036] The example was repeated with the developer at 25°C. At this temperature the speed
of the motor increased under the influence of the temperature sensitive member such
that the plate was developed for 2 minutes 20 seconds. A similar satisfactory resist
was obtained.
[0037] For comparison, a further similar plate was processed with the developer at 25
0C but without the temperature compensation. The plate was therefore developed for
6 minutes and resulted in a badly over-developed resist. The image of the step-wedge
had been cleared to step 6. After further conventional processing it was observed
that the final printing plate was much too dark due to unduly large half-tone dots
and to scum.
Example 3
[0038] Three smooth surfaced sheets of photo-engraving zinc were coated with the positive
working radiation sensitive composition of Example 1 and then exposed and developed
as in that Example. The exposed plates were then etched in a powderless etching bath
for several minutes to produce letter press plates. As before the plates processed
using the temperature compensation device wereindentical and suitable for printing,
whilst the other plate was unsuitable due to the absence of solid areas on examination
of the reproduction of the step-wedge.
Example 4
[0039] Two negative working presentised printing plates consisting of a grained and anodised
substrate having a radiation sensitive coating comprising the cinnamylidenemalonic
acid half ester of poly (2,3-epoxypropyl methacrylate) was exposed beneath a line
and half-tone negative and a continuous tone step-wedge for 1 minute to light from
a mercury halide source. The plates were developed by passing them through the apparatus
of Figures 1 to 3 containing 6% aqueous sodium silicate solution as developer liquid.
In one case the temperature of the developer was 20°C and the development time was
30 seconds. In the other case, the developer temperature was 25 C. and this resulted
in a development time of 20 seconds under the influence of the temperature sensitive
member. In both cases the same reproduction of the step-wedge was obtained.
Example 5
[0040] Example 1 was repeated except that the plates were exposed beneath a continuous tone
positive in place of the half-tone positive and that the apparatus contained a developer
comprising 60g. of sodium metasilicate and 180 ml of polyethylene glycol (M.Wt 300)
per litre of distilled water. Both of the plates processed under the temperature compensated
conditions possessed 10 "grey" steps and 10 solid steps on the step-wedge and satisfactory
reproduction of the positive. The plate processed without temperature compensation
was over developed and the reproduced step-wedge possessed 16 "grey" steps
' but no solid steps.
[0041] The results in this Example were obtained with the potentiometer 15 set to give a
change in output of 0.95V per 1°C change in temperature.
Example 6
[0042] An apparatus similar to that shown in Figure 1 but of a size suitable for film processing
was used to develop a "Plus X" panchromatic film (supplied by Kodak Ltd.) The tank
contained "Microdol X" (Kodak Ltd.) as developer liquid at a temperature of 20°C.
At this temperature the speed of the rollers was such that the film was developed
for 10 minutes. A further similar film was processed with the developer at a temperature
of 24
0C and in this case the development time was 7 minutes.
Example 7
[0043] A temperature compensated apparatus for processing silver halide diffusion transfer
materials was constructed by incorporating in the apparatus described in British Patent
Specification No.1,425,217 a temperature sensitive probe and electrical control circuit
as described with reference to Figures 1 to 3. A sheet of exposed silver halide diffusion
transfer negative paper and a positive receiving sheet in the form of an ADT aluminium
lithographic plate (supplied by the Howson-Algraphy Group of Vickers Ltd.) were fed
together through the apparatus which was filled with an A D T monobath developer/fixer
at 18°C. The apparatus was adjusted to give- an immersion time of 6 seconds. The experiment
was repeated with the monobath at 30°C and in this case the immersion time was 3 seconds.
Example 8
[0044] Three positive working presensitised radiation sensitive plates comprising a grained
and anodised substrate having a radiation sensitive coating based on a quinone diazide
and a novolak resin were identically image-wise exposed beneath a half tone positive.
The first plate was processed face upwards using an apparatus as described in Figure
5 with the tank 41 filled with a developer liquid comprising a 6% aqueous solution
of sodium metasilicate at ambient temperature (20
oC). The apparatus had a path length of 12 inches (about 31 cm) and was driven at a
speed of 30 inches (about 76 cm) per minute. No overall exposure was given and a badly
under developed plate resulted.
[0045] The second plate was processed in the same way except that it was subjected to an
overall exposure as it moved through the apparatus from an actinic radiation source
comprising a
3ft (about 92 cm) 30 watt fluorescent tube 2 cm from the plate path in position 5a.
Thus the overall exposure was given prior to the plate being contacted with the developer
at 20°C. The resultantplate was correctly developed.
[0046] The third plate was processed in the apparatus with the tank 41 filled with a developer
liquid comprising a 6% aqueous solution of sodium metasilicate at 25°C whilst given
a similar overall exposure to that given to the second plate. The speed of motor 44
was controlled by the probe 31 such that the plate speed was 45 inches (about 114
cm) per minute. Results were obtained similar to those obtained in respect of the
second plate.
Example 9
[0047] Three radiation sensitive plates identical to those of Example 8 were exposed beneath
a continuous tone step-wedge to light emitted from a mercury halide lamp for 2i minutes.
The plates were then processed in an apparatus as described in Figure 5 wherein both
the residence time and the width of the radiation source aperture were dependent on
the developer temperature. The tank was filled with a 6% aqueous solution of sodium
metasilicate.
Plate 1 was processed without an overall exposure at a speed of 20 inches (about 51
cm) per min with the developer at 18°C. The final image possessed 6 grey tones (step
2 clear, step 9 solid).
Plate 2 was processed at the same speed and at the same developer temperature but
was also subjected to an overall exposure as it passed through the apparatus by means
of a Philips 300 watt ultra violet lamp spaced 5 cm from the plate path in position
45a. The control circuit was adjusted such that the aperture of the radiation source
was 4 cm wide at the developer temperature (180C). The final image possessed 12 grey tones (step 4 clear, step 17 solid).
Plate 3 was processed using the same apparatus as used for plate 2 but with the developer
at a temperature of 35°C. Because of the increased temperature, the speed of motor
44 increased (and hence the residence time decreased) and the aperture widened to
8 cm. The final image obtained was similar to that of plate 2.
[0048] The apparatus of the present invention provides several advantages over conventional
processors. It is possible to obtain repeatable plate processing accurately without
having to monitor and adjust the working temperature of the developer, which thus
can always be at the ambient temperature. Time is saved when the developer temperature
is low e.g. at the start of processing in a cold environment, as it is not necessary
to wait until the developer is heated to the normal working temperature as is the
case with conventional developers. Further, in the case where the ambient temperature
is higher than the normal working temperature, there is no need to provide a means
of cooling the developer. This is particularly important in the case of large processors
containing 30 or 40 litres of developer.
1. An apparatus for processing an image-wise exposed radiation sensitive device which
apparatus comprises a container (1) (27) (41) for developer liquid and a means (2,
2a)(20, 20a) (23, 23a, 26)(26') (42, 42a) for contacting the device with the developer
liquid characterised in that the apparatus additionallv includes a temperature sensitive
member (5) (28) (31) for sensing the temperature of the developer liauid and for producing
an output signal in denendence on that temnerature and a means (4) (24) (40)(44) (50)
(56, 57, 58)(56, 58, 59) (60, 61) for controlling the processing of the device in
a manner dependent on said output signal whereby the degree to which the device is
processed is dependent on the temperature of the developerliquid.
2. An apparatus as claimed in Claim 1 wherein the means for contacting the device
with the developer liquid comprises a means (2, 2a) (20, 20a) (42,42a) for moving
the device along a path through the developer liquid.
3. An apparatus as claimed in Claim 2 and additionally including a motor (4) (40)(44)
for driving the device moving means (2,2a) (20, 20a) (42, 42a), said temperature sensitive
member (5) (28) (31) being operably connected to said motor (4) (40) (44) so that
said output signal controls the speed of said motor (4) (40) (44) whereby the residence
time of the device in the apparatus is dependent on the temperature of the developer
liquid.
4. An apparatus as claimed in Claim 3 and including a motor (24) for driving a roller
(23, 23a) for agitating the developer liquid in contact with the device, said temperature
sensitive member being additionally operably connected to said motor (24) so that
said output signal also controls the speed of said motor (24) whereby the degree to
which the developer liquid is agitated in contact with the device is also dependent
on the temperature of the developerliquid.
5. An apparatus as claimed in any one of Claims 1 to 4 and additionally comprising
a source of actinic radiation (45a, 45b,45c, 45d, 45e) arranged in or adjacent to
the apparatus so that the processing effected by the apparatus includes subjecting
the device to an overall exposure prior to or during its contact with the developer
liquid, said temperature sensitive member (5) (28) (31) being operably connected to
said source (45a, 45b, 45c, 45d, 45e) so that the output signal controls the source
(45a, 45b, 45c, 45d, 45e) whereby the degree to which the device is subjected to said
overall exposure is dependent on the temperature of the developer liquid.
6. An apparatus as claimed in Claim 5 and additionally including a variable aperture
(56, 57) between the source (45a) and the path wherein the temperature sensitive member
(5) (28) (31) is operably connected to a means (58) of opening and closing the aperture
so that said output signal controls the size of the aperture whereby the degree to
which the device is subjected to said overall exposure is dependent on the temperature
of the developer'1iquid.
7. An apparatus as claimed in Claim 1 wherein the means for contacting the device
with the developer liquid comprises a means (26') of feeding developer liquid to the
device, said temperature sensitive member (5) (28) (31) being operably connected to
a means (60, 61) for regulating said feeding means (26') so that said output signal
controls the feeding means (26') whereby the developer liquid is fed to the device
for a period of time dependent on the temperature of the developer liquid.
8. A method of processing an image-wise exposed radiation sensitive device by contacting
the device with a developer liquid so as to process the device, characterised in that
the temperature of the developer liquid is sensed and the processing of the device
is controlled in a manner dependent on the temperature.
9. A method according to Claim 8 wherein the processing is controlled by controlling
the contact time of the device and the developer liquid.
10. A method according to Claim 8 or 9 wherein the processing is controlled by controlling
the degree to which the device is subjected to an overall exposure to actinic radiation
prior to or during its contact with the developer liquid.