 |
Description  |
|
|
Reference is also hereby made to a co-pending application Ser. No. 168,019,
filed July 14, 1980, now U.S. Pat. No. 4,293,211, entitled AUTOMATIC
REPLENISHER CONTROL SYSTEM and assigned to the same assignee as this
application.
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to an antioxidation replenisher control
system for use in processors of photosensitive material.
2. Description of the Prior Art
Automatic photographic film and paper processors transport sheets or webs
of photographic film or paper through a sequence of processor tanks in
which the photosensitive material is developed, fixed, and washed, and
then transports the material through a dryer. It is well known that
photographic processors require replenishment of the processing fluids to
compensate for changes in the chemical activity of the fluids.
First, it has been recognized that replenishment is necessary to replace
constituents used as photosensitive film or paper is developed in the
processor. This replenishment is "use related" or "exhaustion" chemical
replenishment. Both developer and fix solutions require exhaustion
replenishment.
Second, degradation of the chemical activity of the developer solution due
to aerial oxidation occurs with the passage of time regardless of whether
any film or paper is being processed. Some replenishment systems provide
additional replenishment of an "anti-oxidation" (A-O) replenishment
solution which counteracts this deterioration.
Replenishment systems were originally manually operated. The operator would
visually inspect the processed film or paper and manually operate a
replenisher system as he deemed necessary. The accuracy of the manual
replenisher systems was obviously dependent upon the skill and experience
of the operator.
Various automatic replenishment systems have been developed for providing
use-related replenishment. Examples of these automatic replenishment
systems include U.S. Pat. Nos. 3,472,143 by Hixon et al; 3,529,529 by
Schumacher; 3,554,109 by Street et al; 3,559,555 by Street; 3,561,344 by
Frutiger et al; 3,696,728 by Hope; 3,752,052 by Hope et al; 3,787,689 by
Fidelman; 3,927,417 by Kinoshita et al; 3,990,088 by Takita; 4,057,818 by
Gaskell et al.; 4,104,670 by Charnley et al.; 4,119,952 by Takahashi et
al.; 4,128,325 by Melander et al.; and 4,134,663 by Laar et al. Examples
of prior art replenisher controls for providing both exhaustion and
anti-oxidation replenishment are shown in U.S. Pats. 3,822,723 by Crowell
et al. and 4,174,169 by Melander et al.
SUMMARY OF THE INVENTION
The automatic control system of the present invention recognizes that
generally a processor of photosensitive material is not operated on a
continuous twenty-four hour basis. Oxidation of the replenisher solution,
however, continues even during nonoperating hours of the processor. The
control system of the present invention provides anti-oxidation
replenishment so that the developer solution will have the desired
chemical activity when normal operation of the processor commences again
after a period of nonoperation. The present invention further recognizes
that the rate of aerial oxidation is generally lower during prolonged
nonoperating periods than during normal operation of the processor.
The control system of the present invention, therefore, controls the
providing of anti-oxidation replenishment as a function of operating and
nonoperating periods of the processor. Anti-oxidation replenishment is
provided at a first rate for operating periods; and at a second, lower
rate for non-operating periods.
BRIEF DESCRIPTION OF THE DRAWINGS
The FIGURE is a block diagram illustrating a preferred embodiment of the
automatic anti-oxidation replenishment control system of the present
invention.
DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS
In the system shown in the FIGURE, a photographic processor includes
developer tank 10, fix tank 12, wash tank 14, and dryer 16. Film transport
drive 18 transports the strip or web of photosensitive material (either
film or paper) through tanks 10, 12, 14 and dryer 16. Microcomputer 20
controls operation of film transport 18 and of the automatic replenishment
of fluids to tanks 10, 12 and 14.
The auto-replenishment system shown in the FIGURE includes developer
replenisher 21a and anti-oxidation replenisher 21b for providing
exhaustion and anti-oxidation replenishment, respectively to developer
tank 10. In addition, the system includes fix replenisher 21c for
providing fix replenishment to fix tank 12, and wash replenisher 21d for
providing wash replenishment to wash tank 14.
Developer replenisher 21a includes exhaustion replenishment reservoir 22,
pump 24, pump relay 26, and flow meter or switch 28. Exhaustion
replenishment for developer tank 10 is supplied from exhaustion
replenishment reservoir 22 by means of pump 24. Microcomputer 20 controls
operation of pump 24 through pump relay 26. Flow meter or switch 28
monitors the exhaustion replenishment fluid actually pumped by pump 24 to
developer tank 10, and provides a feedback signal to microcomputer 20.
Anti-oxidation replenisher 21b includes A-O replenisher reservoir 30, pump
32, pump relay 34, and flow meter or switch 36. Anti-oxidation
replenishment is supplied from A-O replenisher reservoir 30 to developer
tank 10 by pump 32. Microcomputer 20 controls operation of pump 32 by
means of relay 34. Flow meter or switch 36 monitors flow of A-O
replenishment to developer tank 10 and provides a feedback signal to
microcomputer 20.
Also shown in the FIGURE is developer circulation pump 37, which circulates
the developer solution within developer tank 10. Microcomputer 20 controls
operation of developer circulation pump 37.
Fix replenisher 21c includes fix replenisher reservoir 38, pump 40, pump
relay 42, and flow meter or switch 44. Fix replenishment is supplied to
fix tank 12 from fix replenisher reservoir 38 by pump 40, which is
controlled by microcomputer 20 through relay 42. Flow meter or switch 44
monitors flow of replenishment fluid to fix tank 12, and supplies a
feedback signal to microcomputer 20.
Wash replenisher 21d, which includes wash reservoir 46, pump 48, pump relay
50, and flow meter or switch 52, provides replenishment of wash fluid
(typically water) in wash tank 14. The wash fluid is supplied from wash
replenishment reservoir 46, and is pumped to wash tank 14 by pump 48.
Microcomputer 20 controls pump 48 through relay 50, and monitors the flow
of wash replenishment to tank 14 by means of flow meter or switch 52.
Microcomputer 20 utilizes developer counter 56, A-O counter 57, fix counter
58, and wash counter 59 as timers to control replenishment. When, for
example, exhaustion replenishment is required, microcomputer 20 loads a
numerical value (DEVTIME) into developer counter 56, which then begins
counting. Microcomputer 20 energizes relay 26, which actuates pump 24.
When developer counter 56 reaches a predetermined value (such as zero), it
provides an interrupt signal to microcomputer 20, which de-energizes relay
26. The numerical value (DEVTIME), therefore, determines the total amount
of exhaustion developer replenisher pumped into tank 10.
Counters 57, 58 and 59 are operated in a similar manner. The numerical
values loaded into counters 57, 58 and 59 are hereafter referred to as
AOXTIME, FIXTIME and WASHTIME, respectively.
AOX timer 60 is a free running timer which provides an interrupt signal to
microcomputer 20 on a periodic basis to initiate A-O replenishment. In one
preferred embodiment, AOX timer 60 provides the interrupt signal every
22.5 minutes.
Microcomputer 20 also receives signals from film width sensors 62 and
density scanner 64. Film width sensors 62 are positioned at the input
throat of the processor, and provide signals indicating the width of the
strip of photosensitive material as it is fed into the processor. Since
microcomputer 20 also controls film transport 18, and receives feedback
signals from film transport 18, the width signals from film width sensors
62 and the feedback signals from film transport 18 provide an indication
of the area of photosensitive material being processed.
Density scanner 64 senses density of the processed photosensitive material.
The signals from density scanner 64 provide an indication of the
integrated density of the processed photosensitive material. The
integrated density, together with the area of material processed, provides
an indication of the amount of processor fluids used in processing that
material.
Microcomputer 20 also receives signals from control panel 66, which
includes function switches 68, keyboard 70, and display 72. Function
switches 68 select certain functions and operating modes of the processor.
Keyboard 70 permits the operator to enter numerical information, and other
control signals used by microcomputer 20 in controlling operation of the
processor, including replenishment. Display 72 displays message or
numerical values in response to control signals from microcomputer 20.
The A-O replenishment control system of the present invention includes real
time clock 74. Real time clock 74 maintains the time of day, and
preferably is provided with battery backup power so that it continues to
operate even when power to the processor is turned off.
Microcomputer 20 preferably stores set values for each of a plurality of
photosensitive materials that may be processed in the processor. Each
group of set values includes pump rates for pump 24 (DEVPMRTE), pump 32
(AOXPMRTE), pump 40 (FIXPMRTE) and pump 48 (WASHPMPRTE); desired
replenishment rates of exhaustion developer (DEVRATE) A-O replenishment
(AOXRATE), fix replenishment (FIXRTE), and wash replenishment (WASHRATE).
When operation is commenced, the operator selects one of the groups of set
values which corresponds to the particular photosensitive material being
processed. As the leading edge of each strip of photosensitive material is
fed into the processor, film width sensors 62 sense the presence of the
strip, and provide a signal indicative of the width of the strip being fed
into the processor. Width sensors 62 continue to provide the signal
indicative of the width of the strip until the trailing edge of the strip
passes sensors 62. The occurrence of the leading and trailing edges of the
material passing sensors 62, permits microcomputer 20 to determine the
length of the strip. The width and length information for each strip is
stored until the strip has been transported through the processor and
reaches density scanner 64. The area of the strip and the integrated
density of the strip (which is provided by the signals from density
scanner 64), provide an indication of the amounts of developer and fix
which have been exhausted in processing that particular strip.
The present invention is an improved system for automatically controlling
A-O replenishment. For that reason, a detailed description of developer
exhaustion, fix, and wash replenishment is not provided in this
application. Reference may be made to the previously mentioned co-pending
patent application entitled "Automatic Replenisher Control System" for
further details.
The anti-oxidation replenishment takes one of two forms, depending upon the
particular developer chemistry used. One type of anti-oxidation
replenishment is known as "blender chemistry", and the other type is known
as "dual" or "two-part chemistry".
Blender chemistry is based upon a "minimum daily requirement" of
anti-oxidation replenishment. This minimum daily requirement is dependent
upon the amount of aerial oxidation which occurs in developer tank 10,
which in turn is dependent upon the open surface area of tank 10, the
operating temperature of the developer solution, and a number of other
factors. With blender chemistry, some anti-oxidation replenishment is
provided each time anti-oxidation replenishment is provided each time
exhaustion replenishment occurs. The more exhaustion replenishment
provided, the less separate anti-oxidation replenishment is required.
For two-part chemistry, on the other hand, the anti-oxidation replenishment
is independent of exhaustion replenishment. Two-part chemistry
replenishment is based upon a daily requirement of anti-oxidation
replenishment, which is unaffected by the amount of material processed in
the processor and the amount of exhaustion replenishment provided.
The replenishment control system of one preferred embodiment of the present
invention controls anti-oxidation replenishment on the basis of 22.5
minute intervals. During a twenty-four hour day, there are sixty-four
intervals of 22.5 minutes each. AOX timer 60 provides interrupt signals to
microcomputer 20 at the 22.5 minute intervals.
In the case of blender chemistry replenishment, microcomputer 20 adjusts
the amount of antioxidation replenishment at the end of each 22.5 minute
interval as a function of the amount of exhaustion replenishment which was
provided during the 22.5 minute interval. If no film or paper has been run
through the processor during the 22.5 minute interval, so that no
exhaustion replenishment has occurred, microcomputer 20 actuates relay 34
to run pump 32 for a time period sufficient to provide 1/64th of the
minimum daily requirement. If exhaustion replenishment has occurred during
the 22.5 minute interval, microcomputer 20 reduces the operating time of
pump 32 accordingly. If film or paper is being processed at a high enough
rate during the 22.5 minute interval, no blender anti-oxidation
replenishment is required, and microcomputer 20 does not activate pump 32.
In the case of two-part chemistry, microcomputer 20 actuates relay 34 at
the end of each 22.5 minute interval. Relay 34 is energized for a period
long enough to permit pump 32 to pump 1/64th of the daily requirement of
two-part chemistry replenishment.
Anti-oxidation replenishment is real time dependent, not simply operating
time dependent. In other words, aerial oxidation of the developer solution
continues even during those hours that the processor is turned off and no
material is being processed. This, of course, is the usual situation in
many businesses--the processor is not operated at night or on the
weekends.
The problem which can be encountered with extended nonoperating periods is
that the chemical activity of the developer solution continues to degrade
due to aerial oxidation, although at a somewhat lower rate than when the
processor is up to temperature and operating. When the processor is again
started, the chemical activity of the developer solution is out of range,
and it takes some time before the developer solution can be replenished to
a point at which it can be used. This results in lost production time at
the beginning of each day.
In general, the longer the period in which the processor is not operated,
the greater the amount of aerial oxidation which can occur. When the
processor is not used over a weekend, the problem can be even worse than
when the processor is not used overnight.
The anti-oxidation replenishment control system of the present invention
solves these problems by use of real time clock 74, which maintains the
current time of day. Microcomputer 20 stores an operating schedule for the
processor for each day of the week. In the preferred embodiment, this
operating schedule is in terms of a TIMEON time and a TIMEOFF time for
each day of the week. This schedule of operating and nonoperating times is
entered into microcomputer 20 by the operator through keyboard 70.
In some facilities, there are restrictions against leaving power on to the
processor during nonoperating hours. In this type of situation, the
present invention replenishes anti-oxidation replenishment on power up
after any down time.
When the processor is initially turned on, the POWER switch is first turned
to the standby position. Microcomputer 20 calculates the bulk
anti-oxidation replenishment based upon the difference between the actual
time (ACTIME) and the last time off time.
It then calculates the bulk amount of anti-oxidation replenishment which
should be added as a function of the actual time of day (ACTIME) and the
last time (TIMEOFF) when the processor was turned off. Microcomputer 20
then calculates AOXTIME, which is loaded into anti-oxidation counter 57
and energizes relay 34. When counter 57 reaches zero, pump 32 is turned
off, thereby ending the bulk anti-oxidation replenishment.
When there are no restrictions at the processor installation point against
continuously leaving the processor with a live electrical input (i.e. even
during normal nonoperating hours), the anti-oxidation replenishment system
of the present invention replenishes on a real time twenty-four hour
schedule. If the processor is not being used, microcomputer 20 activates
anti-oxidation replenishment pump 32 as required. After a suitable
replenishment time, microcomputer 20 turns off pump 32 and shuts down the
processor until the end of the next interval (e.g. 22.5 minutes) when
anti-oxidation replenishment is again provided.
In this preferred embodiment of the present invention, microcomputer 20
also preferably turns the processor on in the morning and off at night.
The turn-on time is preferably selected so that the processor is
replenished, up to temperature, and ready for operation at the beginning
of the normal work day.
When extended non-operating periods are scheduled, such as over a weekend,
microcomputer 20 also preferably adjusts either the bulk additions or the
periodic additions of anti-oxidation replenishment accordingly. Since
extended non-operating periods normally mean that the temperature of the
developer solution will eventually reach room temperature, the rate of
aerial oxidation will be affected, since it is temperature dependent. In
one preferred embodiment, microcomputer 20 determines whether the
nonoperating period exceeds twenty-four hours, the replenishment rate
(AOXRTE) for the bulk additions or the periodic nonoperating hours
replenishment is divided in half (or by some other selected value K which
reflects the reduced aerial oxidation during non-operating hours). If the
anti-oxidation replenishment rate were not reduced to compensate for the
lower oxidation during nonoperating periods, overreplenishment could
occur.
In another preferred embodiment, microcomputer 20 maintains accumulated
time values T1 and T2, representing accumulated operating and nonoperating
time during each 22.5 minute interval. If the processor is continuously
"ON" during the interval, T1=22.5 minutes and T2=0. Conversely, if the
processor is continuously "OFF" during the interval, T1=0 and T2=22.5
minutes. When the processor changes from "ON" to "OFF" or vice versa
during the interval, T1 and T2 both have non-zero values which total 22.5
minutes.
Table B illustrates how microcomputer 20 determines and controls
anti-oxidation replenishment for both during normal operating hours and
nonoperating hours. Step B.15 is specifically concerned with the
embodiment of the present invention in which bulk additions are made upon
power up of the processor. Step B.16 is concerned with the embodiment of
the present invention in which anti-oxidation replenishment continues at
22.5 minutes intervals on a twenty-four hour basis, even throughout the
non-operating hours.
TABLE B
______________________________________
B.1 AOX timer 60 times out (22.5 min.) free run)
B.2 If BLENDER chemistry then
(1) AOXREPL =
##STR1##
(2) Reset AOXDEV, T1, T2
##STR2##
(i.e.) if TWO-PART chemistry), Reset T1, T2
B.3 AOXTIME =
AOXREPL .div. AOXPMPRT + AOXMINRUN
B.4 If AOXTIME less than 7.5 seconds then
(1) Calculate AOXMINRUN =
AOXMINRUN + AOXTIME
(2) Return to B.1
B.5 Output AOXTIME to counter 57
B.6 Trigger pulse sent to counter 57 and
(1) Replenish flag (AOX) set
B.7 Counter 57 begins decrementing and
(1) Anti-ox replenishment pump 32 runs
(2) When counter 57 times out go to B.10
B.8 If flow switch 36 does not activate and/or
Anti-ox replenishment pump relay 34 does not
energize then ERROR
B.9 If pump enable is turned off while counter 57
is running then
(1) Wait 5 seconds
(2) If change then resume B.7
else
(a) Read value remaining in counter 57 to AOXREM
(b) Clear counter 57
(c) Replenish flag (AOX) reset
(d) Return to B.1
B.10 Counter 57 times out and
(1) Interrupt request generated
B.11 If Interrupt request not acknowledged then wait;
else
B.12 If flow switch 36 remains activated and/or pump
relay 34 remains energized, then ERROR; else
B.13 Reset replenish (AOX) flag and AOX not complete
flag and clear AOXMINRUN
B.14 Return to B1 or if TIMEOFF to B.16
B.15 If POWER switch changes to ON or timer to TIMEON
(1) Generate high priority interrupt
(2) Calculate BULKAOX =
(ACTIME - TIMEOFF)* (AOXRATE .div. (144*K)
(3) Calculate BULKTIME =
BULKAOX .div. AOXPMRTE
(4) If BULKTIME is less than 715 seconds then
(a) Clear BULKTIME
(b) Clear BULKAOX
(5) Calculate AOXREPL = BULKAOX
(6) Calculate AOXTIME = BULKTIME
(7) Return to B.5
B.16 If TIME-OFF and AOX timer 60 times out then
go to B.2
______________________________________
Although the specific embodiment of the present invention discussed above
is a system in which anti-oxidation replenishment is provided at fixed
time intervals, with variable amounts of anti-oxidation replenishment
being provided, the present invention is equally applicable to other
anti-oxidation replenishment systems. For example, the present invention
is also applicable to anti-oxidation replenishment systems in which a
fixed amount of anti-oxidation replenishment is provided, but the time
intervals between anti-oxidation replenishment vary as a function of the
amount of exhaustion replenishment provided. An example of a system of
this type is shown in U.S. Pat. No. 4,174,169 by Melander et al., which is
assigned to the assignee of the present application. In the Melander
patent, a predetermined value is set in a counter at the beginning of each
anti-oxidation replenishment interval. The counter is counted down at a
rate representative of aerial aoxidation, and is counted up whenever
exhaustion replenishment occurs. The effect of this operation is to
provide anti-oxidation replenishment at a variable time interval which
depends upon the amount of exhaustion replenishment provided during the
interval. In another embodiment of the present invention, two rates of
counting down the counter in the system of Melander et al. are provided.
The first, higher rate or frequency is used when the processor is
operating, and a second, lower rate or frequency is used to count down the
counter during nonoperating periods. This has the effect of providing
longer time intervals between anti-oxidation replenishment as a result of
nonoperating time of the processor, while still providing the necessary
anti-oxida | | |
