Thermal master making device and thermal printer including the same

Information

  • Patent Grant
  • 6747682
  • Patent Number
    6,747,682
  • Date Filed
    Friday, February 2, 2001
    23 years ago
  • Date Issued
    Tuesday, June 8, 2004
    20 years ago
Abstract
A thermal master making device and a thermal printer including the same are disclosed. A thermistor senses ambient temperature around a thermal head. A correcting device corrects the amount of heat to be generated by the thermal head, i.e., the duration of energization at least two times during a single master making operation. This configuration reduces a change in the perforation conditions of a thermosensitive medium ascribable to the heat accumulation characteristic of the head. The printer achieves high resolution, high-speed master making and space saving.
Description




BACKGROUND OF THE INVENTION




The present invention relates to a thermal master making device for perforating a thermosensitive stencil or similar thermosensitive medium with heat to thereby make a master and a thermal printer including the same.




A digital thermal printer is conventional that uses a thermosensitive stencil as a thermosensitive medium. The thermal printer includes a thermal head having a number of heat generating elements that are arranged in an array in the main scanning direction. The heat generating elements selectively generate heat in accordance with an image signal representative of a document image so as to perforate a stencil. The perforated stencil, or master, is wrapped around a print drum including a porous portion. A press roller or similar pressing member presses a paper sheet or similar recording medium against the master. As a result, ink fed from the inside of the print drum is transferred to the paper sheet via the porous portion of the print drum and the perforations of the stencil, printing an image on the paper sheet.




More specifically, a platen roller is rotated while pressing the master against the thermal head. While the platen roller conveys the master in the subscanning direction perpendicular to the main scanning direction, the heating elements repeatedly generate heat in accordance with the image signal to thereby perforate the stencil.




The base temperature of the thermal head, i.e., the temperature at which the head starts generating heat varies with the environment in which the printer is operated. A change in base temperature translates into a change in peak temperature which Joule heat generated by the heat generating elements is expected to reach, effecting the configuration of perforations. For example, if the base temperature rises, then the area exceeding the perforation threshold of a stencil and the perforation diameter increase. Conversely, the perforation diameter decreases in a low temperature range. Further, the thermal response of the stencil itself is dependent on the environment. The thermal response refers to a period of time necessary for the stencil to reach a threshold. Consequently, a change in ambient temperature results in a change in perforation condition and therefore effects the quality of a print.




High resolution, high-speed master making and space saving (including compact design and low cost) are required of a modern thermal master making device. In practice, there are required resolution of 600 dpi (dots per inch) for size A


3


, master making speed of 2 milliseconds per line higher than the conventional 3 milliseconds per line, and the size reduction of a thermal head. The size reduction of a thermal head leads to high yield and low cost.




The above requirements, however, cannot be met without further aggravating the ill effect of a heat accumulation characteristic particular to a thermal head and therefore without causing the perforation conditions to vary, as will be described more specifically later.




A relation between a thermal head featuring high resolution, high-speed master making and space saving and the heat accumulation characteristic will be described hereinafter. As for high resolution, when the resolution of a thermal head is simply increased from 400 dpi to 600 dpi for size A


3


, the number of heat generating elements to generate heat increases. Therefore, for given thermal response of a stencil, the amount of heat to be generated simply increases. Further, an increase in the resolution of a thermal head translates into a decrease in the size of the individual heat generating element. Therefore, to guarantee a required amount of heat, it is necessary to raise the peak of Joule heat for given drive conditions. It follows that for a given level of heat output form a thermal head itself, resolution increases the amount of heat to accumulate in the head if simply increased. The level of heat is determined by the surface area of an aluminum radiation plate.




When the master making speed is increased, not only the duration of current supply to the heat generating elements of a thermal head, but also the duration of interruption of current supply (release of heat). Also, a stencil must be conveyed at a higher speed with the result that heat transfer efficiency from the heat generating elements to the stencil is lowered. Consequently, high-speed master making needs higher Joule heat than low-speed master making and therefore increases the amount of heat to accumulate in the head.




As for space saving, a decrease in the size of a thermal head itself results in a decrease in the size of the aluminum radiation plate and therefore in the thermal capacity of the head, i.e., a period of time necessary for the base temperature to rise. This, coupled with the fact that the surface area of the radiation plate decreases, reduces the amount of heat to be released to the outside and thereby increases the amount of heat to accumulate in the head.




As stated above, a thermal head satisfying the previously stated conditions causes more heat to accumulate therein than conventional. We experimentally found that such heat aggravated a difference in perforation condition between the leading edge portion and the tailing edge portion of a single master, which has not been addressed to in the past. Particularly, when image data had a high print ratio in the main and subscanning directions, the perforation diameter became far greater than a designed value in the trailing edge portion of a master, resulting in offset.




Moreover, irregularity in the various portions of a thermal head effects perforations. It was experimentally found that in, e.g., a portion where the resistance of the head approached the lower limit away from a mean value, perforations formed by the heat generating elements joined each other in the subscanning direction and lowered the resistance of a master to repeated printing. This is because in the case of constant voltage drive the heat generating elements whose resistance is lower than the mean value generate more heat than the others. Likewise, in a portion where perforations were formed by a small amount of heat, perforations formed by the heat generating elements joined each other in the subscanning direction and also lowered the resistance of a master to repeated printing.




Technologies relating to the present invention are disclosed in, e.g., Japanese Patent Laid-Open Publication Nos. 8-90746 and 11-115145, U.S. Pat. Nos. 5,685,222, 5,809,879, and GB 2277904A and 2294906A.




SUMMARY OF THE INVENTION




It is therefore an object of the present invention to provide a thermal master making device capable of obviating a difference in perforation condition between the leading edge portion and the trailing edge portion of a master as well as offset and low resistance to repeated printing, and a thermal printer including the same.




It is another object of the present invention to provide a low cost, thermal master making device using a conventional construction as far as possible, and a thermal printer including the same.




In accordance with the present invention, a thermal master making device includes a thermal head having a plurality of heat generating elements arranged in an array in the main scanning direction. A thermosensitive medium is moved relative to the head in the subscanning direction perpendicular to the main scanning direction while pressing the medium against the head. The heat generating elements repeatedly generate heat in accordance with an image signal to thereby make a master. The master making device includes a sensor for sensing ambient temperature around the head, and a correcting circuit configured to correct the amount of heat to be generated by the head in accordance with the ambient temperature sensed by the sensor. The amount of heat is corrected on the basis of the ambient temperature during master making operation.




A thermal printer including the above-described thermal master making device is also disclosed.











BRIEF DESCRIPTION OF THE DRAWINGS




The above and other objects, features and advantages of the present invention will become more apparent from the following detailed description taken with the accompanying drawings in which:





FIG. 1

is a graph showing a relation between the base temperature of a thermal head and the perforation diameter;





FIG. 2A

is a view showing a specific configuration of perforations formed at room temperature;





FIG. 2B

is a graph showing a relation between heating temperature and a perforation threshold;





FIG. 3A

is a view showing specific perforations formed at low temperature;





FIG. 3B

is a graph showing a relation between heating temperature and a perforation threshold;





FIG. 4A

is a view showing specific perforations formed at high temperature;





FIG. 4B

is a graph showing a relation between heating temperature and a perforation threshold;





FIG. 5

is a plan view showing a conventional thermal head;





FIG. 6

is a timing chart demonstrating conventional correction control based on ambient temperature;





FIG. 7A

is a plan view showing a specific configuration of a conventional thermal head;





FIG. 7B

is a section taken in a plane a-b shown in

FIG. 7



a;







FIG. 8

is a circuit diagram representative of the conventional thermal head;





FIG. 9

is a block diagram schematically showing a conventional control system for a thermal master making device;





FIG. 10

is a timing chart showing conventional common drop correction;





FIG. 11

is a table showing a conventional relation between ambient temperature and print ratio data;





FIGS. 12 and 13

are fragmentary sections showing how heat is radiated from the conventional thermal head;





FIG. 14

is a view showing a thermal printer embodying the present invention;





FIG. 15

is a block diagram schematically showing a control system included in the illustrative embodiment;





FIG. 16

is a timing chart demonstrating correction control unique to the illustrative embodiment;





FIG. 17

is a graph showing a specific transition of temperature sensed by a thermistor included in the illustrative embodiment;





FIG. 18

is a graph showing the transition of a perforation area ascribable to heat accumulated in a thermal head;





FIG. 19

is a graph showing the transition of perforation area ascribable to temperature difference;





FIG. 20

is a table showing a relation between ambient temperature and print ratio data;





FIG. 21

is a schematic block diagram showing a control system representative of an alternative embodiment of the present invention; and





FIG. 22

is a schematic block diagram showing a control system representative of another alternative embodiment of the present invention.











DESCRIPTION OF THE PREFERRED EMBODIMENTS




To better understand the present invention, problems with a thermal printer including a thermal head will be described specifically. The base temperature of the thermal head itself is susceptible to the environment in which the stencil printer is operated, as stated earlier. A change in base temperature translates into a change in peak temperature which Joule heat generated by the heat generating elements of the thermal head is expected to reach, effecting the configuration of perforations.




For example, as shown in

FIG. 1

, if the base temperature rises from B


1


to B


2


, then the area exceeding the perforation threshold of a thermosensitive stencil or similar thermosensitive medium varies from K


1


to K


2


while the perforation diameter increases from D


1


to D


2


. Conversely, the perforation diameter decreases in a low temperature range. Further, the thermal response of the stencil itself is dependent on the environment.




More specifically,

FIGS. 2A and 2B

show a specific reference or optimal perforation condition achievable at room temperature (around 23° C.). Assume that the thermal head is driven in a low temperature environment (lower than room temperature) by the same drive energy as in the room temperature environment. Then, as shown in

FIGS. 3A and 3B

, the head fails to perforate some portions of the stencil that it should perforate, resulting in an image partly lost in the form of white spots.




Conversely, in a high temperature environment (higher than room temperature), the perforation diameter of the stencil exceeds a designed diameter and causes excess ink to flow out to bring about so-called offset. In the worst case, as shown in

FIGS. 4A and 4B

, nearby perforations join each other and reduce the strength of the stencil. As a result, the perforated stencil or master cannot withstand repeated printing, i.e., elongates an image or tears itself. That is, the resistance of the stencil to repeated printing is lowered.





FIG. 5

shows a conventional solution to the above-described problems. As shown, a thermistor


302


is positioned in contact with or in the vicinity of a thermal head


300


for sensing ambient temperature around the head


300


. Immediately before the start of a master making operation, the thermistor


302


senses the ambient temperature. Current is fed to the head


300


for an optimal period of time matching with the output of the thermistor


302


and experimentally determined beforehand. The optimal period of time or duration is read out of a table. Stated another way, drive energy for driving the thermal head


300


is controlled in accordance with the ambient temperature at the time of the start of a master making operation. The head


300


includes an array of heat generating elements


304


, an IC (Integrated Circuit) cover


306


, a power source connector


308


, and a signal connector


310


.




More specifically, as shown in

FIG. 6

, the thermistor


302


senses the ambient temperature around the head


300


once before the start of a master making operation. Current is fed to the head


300


for an optimal period of time matching with the sensed temperature, so that constant perforations (images) can be formed in successive masters. The thermistor


302


repeatedly senses the ambient temperature at a preselected period up to a time S at which the duration of energization, or current supply to the head


300


, is set. The duration of energization is selected and set in accordance with the last output of the thermistor


302


appeared before the start of a master making operation. In

FIG. 6

, a conveyance motor refers to a motor that drives a platen roller not shown.




The previously mentioned table lists both of ambient temperatures and optimal durations of energization each corresponding to a particular ambient temperature level stepwise. Specifically, a range between 10° C., which is the lower limit of operation temperature of a stencil printer, and 54° C., which is the upper limit of the same, is equally divided into sixteen. In this case, the duration of energization is varied on a 2.75° C. basis. A step of 2.75° C. is based on experimental results showing that for given head drive conditions, a difference in ambient temperature that renders differences in picture conspicuous is 2.75° C. or above. The differences in picture pertain to density, ink consumption, offset and so forth. Stated another way, when the difference in ambient temperature is less than 2.75° C., factors other than the differences in the perforation conditions of the stencil have great influence on a picture.




It is a common practice with the stencil printer to correct the amount of heat in accordance with the number of heat generating elements (resistors) to be driven at the same time, i.e., to effect so-called common drop correction.

FIGS. 7A and 7B

show a typical thin film, line type thermal head customary with a stencil printer. As sown, this type of thermal head includes a ceramic substrate


312


, a glaze layer or heat insulation layer


314


formed on the substrate


312


, a resistance layer


316


formed on the glaze layer


314


, a common electrode


318


, individual electrodes


320


, and a protection film


322


covering the electrodes


318


and


320


. The resistance layer


316


is exposed between the common electrode


318


and the individual electrodes


320


, forming heat generating elements


324


.




The thermal head of the type shown in

FIGS. 7A and 7B

allows fine heat generating elements essential for the stencil printer to be produced at low cost. However, this type of head is susceptible to a common drop because it has the heat generating elements arranged as shown in

FIG. 8. A

common drop refers to an occurrence that much current flows in accordance with the number of heat generating elements driven at the same time and makes wiring resistance not negligible, thereby lowering voltage to be actually applied to the heat generating elements. A decrease in voltage directly translates into a decrease in head drive energy. This reduces the perforation diameter and therefore causes many white spots to appear in the resulting image.





FIGS. 9 and 10

show a conventional measure taken against a common drop. As shown, the number of heat generating elements to be driven at the same time is determined on the basis of image data. A range between the print ratios of 0% and 100% is equally divided into sixteen. An optimal duration of energization matching with print ratio data and experimentally determined beforehand is selected out of a table. Specifically, in

FIG. 10

, a duration of energization is selected and calculated in a range F and fed to a duration generating counter that generates a duration of energization.




In practice, the correction based on the ambient temperature and the correction based on print ratio data (common drop correction) are executed in combination. Specifically, as shown in

FIG. 11

, sixteen patterns of duration data based on ambient temperature and sixteen patterns of duration data based on print ratio data are determined by experiments beforehand. Such patterns are listed in a 16×16 matrix on a table, showing a relation between ambient temperature and print ratio.




Before the start of a master making operation, data representative of a duration of energization, which corresponds to the ambient temperature, is selected and narrowed down to sixteen patterns, i.e., a region A is selected. After the start of the master making operation, data corresponding to the print ratio data is selected from the above sixteen patterns, i.e., a region B is selected. Duration data located at a position where the regions A and B cross each other is fed to the duration generating counter, FIG.


9


. The above data are sometimes determined by calculation instead of experiment.




High resolution, high speed perforation, space saving (including compact design and low cost) and so forth are required of a master making device included in a modern stencil printer, as also stated earlier. Such demands, however, cannot be met without further aggravating the ill effect of a heat accumulation characteristic particular to a thermal head and therefore without varying the configuration of perforations. This will be described more specifically hereinafter.





FIG. 12

shows a thermal head configured to efficiently transfer heat to a stencil or similar thermosensitive medium with small energy. As shown, the thermal head, labeled


300


, includes a heat generating element


324


that generates Joule heat


326


. The Joule heat tends to spread spherically in all directions. On the other hand, as shown in

FIG. 13

, a stencil


328


moves on a protection layer


322


. An insulation layer


314


blocks heat


330


tending to spread downward below the heat generating element


324


, so that more heat is released toward the stencil


328


above the protection layer


322


.




Excessively perforating a stencil with much heat is not desirable. Ideally, each heat generating element should form a single perforation in a stencil, so that all the expected perforations are formed and separate from each other. It is therefore necessary to fully release heat as soon as a single perforation is formed. However, releasing the entire heat cannot be done without resorting to a substantial period of time and is impracticable with a line type thermal head.




Moreover, a glaze layer


314


stores heat in order to efficiently transfer heat to the stencil


328


with small energy. Consequently, a substantial amount of heat is not released, but is accumulated in the thermal head. It follows that repeated heat generation causes the temperature of the head, i.e., the base temperature to rise little by little, causing the configuration of perforations to vary between the leading edge portion and the trailing edge portion of a master. More specifically, the perforation diameter sequentially increases from the leading edge toward the trailing edge of a master.




As stated above, a thermal head meeting the previously stated demands would accumulate more heat than the conventional thermal head and would thereby aggravate offset while lowering the resistance of a master to repeated printing.




Referring to

FIG. 14

, a stencil printer including a thermal master making device embodying the present invention will be described. As shown, the stencil printer includes a housing or cabinet


50


. A scanning section


80


for reading a document is arranged in the upper portion of the housing


50


. A thermal master making device


90


is positioned below the scanning section


80


. A print drum section


100


is located at the left-hand side of the master making section


90


, as viewed in

FIG. 14

, and includes a porous print drum


101


. A master discharging section


70


is arranged at the left-hand side of the print drum section


100


, as viewed in

FIG. 14. A

paper feeding section


110


is located below the master making section


90


. A pressing section


120


is positioned beneath the print drum


101


. A paper discharging section


130


is arranged in the bottom left portion of the housing


50


.




In operation, the operator of the printer sets a desired document


60


on a tray, not shown, arranged on the top of the scanning section


80


and then presses a perforation start key not shown. In response, the printer starts discharging a used master. Specifically, a master


61




b


used to print images last time is left on the outer periphery of the print drum


101


. First, the print drum


101


with the used master


61




b


is rotated counterclockwise, as viewed in

FIG. 14



l.


As the trailing edge of the used master


61




b


approaches a pair of peel rollers


71




a


and


71




b


being rotated, the peel roller


71




b


picks up the trailing edge of the master


61




b


. A pair of conveyor belts


72




a


and


72




b


are passed over the peel rollers


71




a


and


71




b


and a pair of discharge rollers


73




a


and


73




b


, which are positioned at the left-hand side of the rollers


71




a


and


71




b


. The conveyor belts


72




a


and


72




b


convey the used master


61




b


separated from the print drum


101


by the peel rollers


71




a


and


71




b


in a direction Y


1


. The used master


61




b


is then introduced into a waste master box


74


. At this instant, the print drum


101


is continuously rotated counterclockwise. A plate


75


compresses the used master


61




b


in the waster master box


74


.




In parallel with the master discharging step described above, the scanning section


80


reads the document. Specifically, a pickup roller


81


, a pair of front rollers


82




a


and


82




b


and a pair of rear rollers


83




a


and


83




b


in rotation sequentially convey the document


60


laid on the tray in directions Y


2


and Y


3


. When the operator stacks a plurality of documents on the tray, a separator in the form of a blade


84


causes only the bottom document to be fed from the tray. A motor


83


A drives the rear roller


83




a


and drives the front roller


82




a


via a timing belt, not shown, passed over the rear roller


83




a


and the front roller


82




a


. The rollers


82




b


and


83




b


are driven rollers.




Specifically, the scanning section


80


includes a lamp or light source


86


. While the document


60


is conveyed on and along a glass platen


85


, the lamp


86


illuminates the document


60


. The resulting imagewise reflection from the document


60


is incident to a CCD (Charge Coupled Device) image sensor or similar image sensor


89


via a mirror


87


and a lens


88


. In this manner, the document


60


is read by a conventional reduction type of document reading system. The document


60


is then driven out to a tray


80


A. An electric signal output from the image sensor


89


is input to an analog-to-digital converter, not shown, disposed in the housing


50


and converted to a digital image data thereby.




In parallel with the document reading step described above, a master making and feeding step is executed in accordance with the digital signal or image data output from the analog-to-digital converter. Specifically, a thermosensitive stencil


61


implemented as a roll is set in a preselected portion of the master making device


90


and paid out from the roll. A platen roller


92


presses the stencil


61


against a thermal head


30


. The platen roller


92


and a pair of rollers


93




a


and


93




b


, which are in rotation, cooperate to convey the stencil


61


intermittently to the downstream side.




A number of fine, heat generating portions are arranged on the head


30


in an array in the main scanning direction. The heat generating portions selectively generate heat in accordance with the digital image data sent from the analog-to-digital converter. The heat generating portions generating heat melt and thereby perforate the portions of a thermosensitive resin film, which is included in the stencil


61


, contacting the heat generating portions. As a result, a perforation pattern is formed in the stencil


61


in accordance with the image data.




A pair of rollers


94




a


and


94




b


convey the leading edge of the perforated stencil


61


, i.e., the leading edge of a master


61




a


toward the outer periphery of the print drum


101


. A guide member, not shown, steers the master


61




a


downward with the result that the master


61




a


hangs down toward a damper


102


mounted on the print drum


101


. At this time, the damper


102


is held open at a master feed position, as indicated by a phantom line in FIG.


14


.




At a preselected timing, the damper


102


clamps the leading edge of the master


61




a


. The print drum


101


is then rotated in a direction A (clockwise) while wrapping the master


61




a


therearound. After the entire master


61




a


has been formed, a cutter


95


cuts it off at a preselected length. This is the end of the master making and feeding step.




The master making and feeding step is followed by a printing step. A stack of paper sheets or similar recording media


62


are stacked on a tray


51


. A pickup roller


111


and a pair of separator rollers


112




a


and


112




b


pay out the top paper sheet


62


toward a pair of feed rollers


113




a


and


113




b


in a direction Y


4


. The feed rollers


113




a


and


113




b


convey the paper sheet


62


toward the pressing section


120


at a preselected timing synchronous to the rotation of the print drum


101


. When the paper sheet


62


arrives at a position between the print drum


101


and the press roller


103


, the press roller


103


is moved upward in order to press the paper sheet


62


against the master


61




a


wrapped around the print drum


101


. Consequently, ink oozes out via the porous portion of the print drum


101


, not shown, and the perforations of the master


61




a


. The ink is then transferred to the surface of the paper sheet


62


, forming an ink image.




Specifically, an ink feed tube


104


, an ink roller


105


and a doctor roller


106


are disposed in the print drum


101


. Ink is fed from the ink feed tube


104


to an ink well


107


between the ink roller


105


and the doctor roller


106


. The ink roller


105


, which contacts the inner periphery of the print drum


101


, is rotated in the same direction as and in synchronism with the print drum


101


, feeding the ink to the inner periphery of the print drum


101


. The ink is implemented by W/O type emulsion ink.




A peeler


114


peels off the paper sheet


62


, which carries the ink image thereon, from the print drum


101


. A belt


117


is passed over an inlet roller


115


and an outlet roller


116


and turned counterclockwise, as viewed in FIG.


14


. The belt


117


conveys the paper sheet


62


toward the paper discharging section


130


in a direction Y


5


. At this instant, a suction fan


118


retains the paper sheet


62


on the belt


117


by suction. Finally, the paper sheet


62


is driven out to a tray


52


as a trial print.




If the trial print is acceptable, the operator inputs a desired number of prints on numeral keys, not shown, and then presses a print start key not shown. In response, the printer repeats the paper feeding step, printing step and paper discharging step a number of times corresponding to the desired number of prints.




Reference will be made to

FIG. 15

for describing a control system that controls the master making device


90


. As shown, the master making device


90


includes a thermistor


200


, an image data counter


202


and a heat correcting section


204


in addition to the previously stated components including the thermal head


30


. The thermistor


200


plays the role of sensing means for sensing ambient temperature around the thermal head


30


. The image data counting


202


serves as detecting means for detecting a print ratio in terms of the number of heat generating elements to be energized at the same time. The heat correcting section


204


corrects the amount of heat to be generated by the thermal head


30


on the basis of the output of the thermistor


200


and the output of the image data counter


202


. This control system is identical with the conventional control system. The thermal head


30


is conventional and will not be described specifically.




The heat correcting section


204


includes a CPU (Central Processing Unit) including a ROM (Read Only Memory) and a RAM (Random Access Memory), a duration memory


210


, a duration generating counter


212


, and a thermal head controller


214


. The entire heat correcting section


204


is implemented as a microcomputer.




It has been customary to correct the amount of heat to be generated by the head


30


only once before the start of a master making operation, as discussed earlier. By contrast, the illustrative embodiment corrects the amount of heat even during master making operation and at least two times for a single master making operation. This successfully prevents the master perforating conditions from varying due to heat accumulated in the thermal head


30


. Specifically, as shown in

FIG. 16

, the illustrative embodiment executes such correction control five times for a single master making operation at intervals C of 5 seconds or less.




Before a time S shown in

FIG. 16

, the illustrative embodiment, like the conventional printer, repeatedly senses ambient temperature around the head


30


with the thermistor


200


at a preselected period. In the illustrative embodiment, the preselected period is selected to be 5 milliseconds.




Why the interval C between the consecutive corrections should be 5 seconds or less will be described hereinafter. In the illustrative embodiment, the head


30


has the following specification and is driven under the following conditions:




Thermal Head Type




size: A


3






resolution: 600 dpi




aluminum radiator size (1×w×t):




316×21×21.4×8 mm




total number of heat generating elements:




7,168 dots




glaze layer thickness: 40 μm (glass glaze)




low heat accumulation structure: using gel




thermistor characteristic values:




R(25)=30 kΩ±5%




B=3,970±80 K




Drive Conditions




line period: 2 ms/l




power applied: 0.0425 W (constant voltage




drive)




maximum number of simultaneous energization:




3,584 dots




duration of energization: 598 μs




correction system: adjustment of duration




When a black solid image sized 303×420 mm was formed in a stencil under the above conditions, the output of the thermistor


200


indicated temperature elevation shown in FIG.


17


. After the start of a master making operation under the above drive conditions, the perforation area, which is one of the perforation conditions, varied as indicated by “no correction” in FIG.


18


. As

FIG. 18

indicates, when the correction is not executed, the perforation area noticeably varies between the time at which a master making operation starts and the time when it ends. This problem is ascribable to heat accumulated in the thermal head


30


and has recently been highlighted in relation to the demands for high resolution, high-speed master making, and space saving.




In light of the above, the correction control was experimentally repeated at the periods of 5 seconds, 3 seconds, 1 second and 5 milliseconds by using the specification of the head


30


and drive conditions mentioned earlier.

FIG. 18

shows the results of such correction control. It will be seen that the correction repeated even during master making operation reduces the variation of the perforation condition. The correction during master making operation further reduces the variation of the perforation condition if repeated at short intervals.




Further, the correction control based on the ambient temperature is executed when the temperature difference is less than 2.75° C. (2° C. in the illustrative embodiment). Assume that the correction based on the ambient temperature is effected when the drive condition (duration of energization) of the head


30


is varied during master making operation. Then, any noticeable change in a printed image before and after the correction is critical. This is why the drive condition of the thermal head


30


is varied if the temperature difference (transitional temperature difference) is 2.27° C. or less that does not bring about the above noticeable change.





FIG. 19

shows the results of experiments in which the transitional temperature difference of the ambient temperature was varied. As

FIG. 19

indicates, the lower the temperature difference for a single step, the transition of the perforation condition is more reduced. Minutely dividing the temperature difference is identical in meaning with reducing the interval between consecutive corrections.




The control of the master making device


90


will be described with reference to

FIGS. 15 and 20

. As shown in

FIG. 20

, there is experimentally determined a combination of twenty-two patterns of duration data based on ambient temperature (step of 2° C.) and sixteen patterns of duration data based on print ratio (common drop correction), i.e., a 22×16 matrix. This matrix is stored in a ROM, not shown, included in the heat correcting section


204


.




Assume that the output of the thermistor


200


representative of the instantaneous ambient temperature is input to the CPU


208


, and that ambient temperature is 27° C. by way of example. Then, the CPU


208


selects a duration data region M corresponding to the ambient temperature and narrows it down to sixteen patterns. Also, assume that the output of the image data counter


202


input to the CPU


208


indicates a print ratio of 60% by way of example. Then, the CPU


208


selects a duration data region N corresponding to the above print ratio.




Subsequently, the CPU


208


selects duration data located at a position where the two regions M and N cross each other, and sends the data to the duration generating counter


212


. The duration generating counter


212


sets the duration therein and feeds it to the thermal head controller


214


. In response, the thermal head controller


214


drives the heat generating elements of the head


30


for the duration set. Such correction control is repeated five consecutive times during a single master making operation.




In the illustrative embodiment, the print ratio detecting means may be omitted, in which case the amount of heat will be corrected alone on the basis of ambient temperature.





FIG. 21

shows an alternative embodiment of the present invention. As shown, this embodiment includes a print ratio data memory or storing means


206


. The data output from the image data counter


202


is written to the print ratio data memory


206


. More specifically, past print ratio data (progress of heat generation) of the individual simultaneous energization block are written to the print ratio data memory


206


. In the illustrative embodiment, the CPU


208


estimates, based on the past print ratio data, the ambient temperature around the thermal head


30


to occur at the time of the next heat generation. The CPU


208


then selects a duration of energization of the head


30


matching with the estimated ambient temperature and experimentally determined beforehand out of a preselected table. The table listing a relation between the ambient temperature and the duration of energization is not shown.




The circuitry of

FIG. 21

may be modified such that the CPU


208


selects, based on the past print ratio data (total number of heat generating elements) stored in the print ratio data memory


206


, a duration of energization of the head


30


experimentally determined beforehand. A table showing a relation between the print ratio data and the duration of energization is not shown. Alternatively, the CPU


208


may select a correction coefficient corresponding to the past print ratio data stored in the memory


206


and determined by experiments beforehand. A table showing a relation between the print ratio data and the correction coefficient is not shown.





FIG. 22

shows another alternative embodiment of the present invention. As shown, this embodiment includes ambient temperature estimating means


216


for estimating, based on the past print ratio data stored in the print ratio data memory


206


, ambient temperature around the thermal heat


30


to occur at the time of the next heat generation. The CPU


208


selects a duration of energization of the head


30


corresponding to the estimated ambient temperature and experimentally determined beforehand. A table showing a relation between the ambient temperature and the duration of energization is not shown.




In summary, it will be seen that the present invention provides a thermal master making device and a thermal printer including the same having various unprecedented advantages, as enumerated below.




(1) The amount of heat to be generated is corrected on the basis of ambient temperature during master making operation. The amount of heat can therefore be controlled in accordance with a change in the heat accumulation characteristic of a thermal head, so that a change in perforation condition is reduced. This successfully realizes high resolution, high-speed master making and space saving required of a thermal master making device while obviating offset and enhancing the resistance of a master to repeated printing.




(2) The amount of heat to be generated is controlled on the basis of data representative of past heat generation. This allows a heat accumulation characteristic particular to a thermal head and the current heat accumulation characteristic to be accurately grasped and thereby insures highly accurate heat correction.




(3) Correction based on ambient temperature and correction based on print ratio data are effected at the same time. This allows the current heat accumulation characteristic of a thermal head to be accurately grasped in manifold aspects and thereby insures highly accurate heat correction.




(4) The master making device achieves high resolution, high-speed master making and space saving at low cost because it is practicable without resorting to any substantial change in conventional basic circuitry.




Various modifications will become possible for those skilled in the art after receiving the teachings of the present disclosure without departing from the scope thereof.



Claims
  • 1. A thermal master making device including a thermal head, which have a plurality of heat generating elements arranged in an array in a main scanning direction, moving a thermosensitive medium relative to said thermal head in a subscanning direction perpendicular to the main scanning direction while pressing said thermosensitive medium against said thermal head, and causing said plurality of heat generating elements to repeatedly generate heat in accordance with an image signal to thereby make a master, said thermal master making device comprising:sensing means for sensing ambient temperature around the thermal head; and correcting means for correcting an amount of heat to be generated by the thermal head in accordance with the ambient temperature sensed by said sensing means; wherein the amount of heat is corrected on the basis of the ambient temperature during master making operation so as to control print quality.
  • 2. A device as claimed in claim 1, wherein the amount of heat is corrected at least two times during a single master making operation.
  • 3. A device as claimed in claim 2, wherein the amount of heat is corrected at an interval of 5 seconds or less.
  • 4. A device as claimed in claim 1, wherein the amount of heat is corrected if a temperature difference is less than 2.75° C.
  • 5. In a thermal printer including a thermal master making device that includes a thermal head having a plurality of heat generating elements arranged in an array in a main scanning direction, moves a thermosensitive medium relative to said thermal head in a subscanning direction perpendicular to the main scanning direction while pressing said thermosensitive medium against said thermal head, and causes said plurality of heat generating elements to repeatedly generate heat in accordance with an image signal to thereby make a master, said thermal master making device comprises:sensing means for sensing ambient temperature around the thermal head; and correcting means for correcting an amount of heat to be generated by the thermal head in accordance with the ambient temperature sensed by said sensing means; wherein the amount of heat is corrected on the basis of the ambient temperature during master making operation so as to control print quality.
  • 6. A thermal master making device including a thermal head, which have a plurality of heat generating elements arranged in an array in a main scanning direction, moving a thermosensitive medium relative to said thermal head in a subscanning direction perpendicular to the main scanning direction while pressing said thermosensitive medium against said thermal head, and causing said plurality of heat generating elements to repeatedly generate heat in accordance with an image signal to thereby make a master, said thermal master making device comprising:sensing means for sensing an ambient temperature around the thermal head; detecting means for detecting a print ratio in terms of a number of heat generating elements to be energized at the same time; and correcting means for correcting an amount of heat to be generated by the thermal head on the basis of the ambient temperature sensed by said sensing means and the print ratio data output from said detecting means, wherein the amount of heat to be generated by the thermal head is corrected during master making operation so as to control print quality.
  • 7. A device as claimed in claim 6, wherein the amount of heat is corrected at least two times during a single master making operation.
  • 8. A device as claimed in claim 7, wherein the amount of heat is corrected at an interval of 5 seconds or less.
  • 9. A device as claimed in claim 6, wherein the amount of heat is corrected if a temperature difference is less than 2.75° C.
  • 10. In a thermal printer including a thermal master making device that includes a thermal head, which have a plurality of heat generating elements arranged in an array in a main scanning direction, moves a thermosensitive medium relative to said thermal head in a subscanning direction perpendicular to the main scanning direction while pressing said thermosensitive medium against said thermal head, and causes said plurality of heat generating elements to repeatedly generated heat in accordance with an image signal to thereby make a master, said thermal master making device comprising:sensing means for sensing an ambient temperature around the thermal head; detecting means for detecting a print ratio in terms of a number of heat generating elements to be energized at the same time; and correcting means for correcting an amount of heat to be generated by the thermal head on the basis of the ambient temperature sensed by said sensing means and the print ratio data output from said detecting means; wherein the amount of heat to be generated by the thermal head is corrected during master making operation so as to control print quality.
  • 11. A thermal master making device including a thermal head, which have a plurality of heat generating elements arranged in an array in a main scanning direction, moving a thermosensitive medium relative to said thermal head in a subscanning direction perpendicular to the main scanning direction while pressing said thermosensitive medium against said thermal head, and causing said plurality of heat generating elements to repeatedly generate heat in accordance with an image signal to thereby make a master, said thermal master making device comprising:a sensor configured to sense ambient temperature around the thermal head; and a correcting circuit configured to correct an amount of heat to be generated by the thermal head in accordance the ambient temperature sensed by said sensor; wherein the amount of heat is corrected on the basis of the ambient temperature during master making operation so as to control print quality.
  • 12. A device as claimed in claim 11, wherein the amount of heat is corrected at least two times during a single master making operation.
  • 13. A device as claimed in claim 12, wherein the amount of heat is corrected at an interval of 5 seconds or less.
  • 14. A device as claimed in claim 11, wherein the amount of heat is corrected if a temperature difference is less than 2.75° C.
  • 15. In a thermal printer including a thermal master making device that includes a thermal head having a plurality of heat generating elements arranged in an array main scanning direction, moves a thermosensitive medium relative to said thermal head in a subscanning direction perpendicular to the main scanning direction while pressing said thermosensitive medium against said thermal head, and causes said plurality of heat generating elements to repeatedly generate heat in accordance with an image signal to thereby make a master, said thermal master making device comprises:a sensor configured to sense ambient temperature around the thermal head; and a correcting circuit configured to correct an amount of heat to be generated by the thermal head in accordance with the ambient temperature sensed by said sensor; wherein the amount of heat is corrected on the basis of the ambient temperature during master making operation so as to control print quality.
  • 16. A thermal master making device including a thermal head, which have a plurality of heat generating elements arranged in an array in a main scanning direction, moving a thermosensitive medium relative to said thermal head in a subscanning direction perpendicular to the main scanning direction while pressing said thermosensitive medium against said thermal head, and causing said plurality of heat generating elements to repeatedly generate heat in accordance with an image signal to thereby make a master, said thermal master making device comprising:a sensor configured to sense an ambient temperature around the thermal head; a detecting circuit configured to detect a print ratio in terms of a number of heat generating elements to be energized at the same time; and a correcting circuit configured to correct an amount of heat to be generated by the thermal head on the basis of the ambient temperature sensed by said sensor and the print ratio data output from said detecting circuit, wherein the amount of heat to be generated by the thermal head is corrected during master making operation so as to control print quality.
  • 17. A device as claimed in claim 16, wherein the amount of heat is corrected at least two times during a single master making operation.
  • 18. A device as claimed in claim 17, wherein the amount of heat is corrected at an interval of 5 seconds or less.
  • 19. A device as claimed in claim 16, wherein the amount of heat is corrected if a temperature difference is less than 2.75° C.
  • 20. In a thermal printer including a thermal master making device that includes a thermal had, which have a plurality of heat generating elements arranged in an array in a main scanning direction, moves a thermosensitive medium relative to said thermal head in a subscanning direction perpendicular to the main scanning direction while pressing said thermosensitive medium against said thermal head, and causes said plurality of heat generating elements to repeatedly generate heat in accordance with an image signal to thereby make a master, said thermal master making device comprising:a sensor configured to sense an ambient temperature around the thermal head; a detecting circuit configured to detect a print ratio in terms of a number of heat generating elements to be energized at the same time; and a correcting circuit for correcting an amount of heat to be generated by the thermal head on the basis of the ambient temperature sensed by said sensor and the print ratio data output from said detecting circuit, wherein the amount of heat to be generated by the thermal head is corrected during master making operation so as to control print quality.
  • 21. A method for making a thermal master using a thermal master making device including a thermal head having a plurality of heat generating elements arranged in an array in a main scanning direction, and a thermosensitive medium moveable relative to said thermal head in a subscanning direction perpendicular to the main scanning direction while pressing said thermosensitive medium against said thermal head so as to cause said plurality of heat generating elements to repeatedly generate heat in accordance with an image signal, said method comprising:sensing ambient temperature around the thermal head; and correcting an amount of heat to be generated by the thermal head in accordance with the ambient temperature sensed during master making operation so as to control print quality.
  • 22. A method for making a thermal master using a thermal master making device including a thermal head having a plurality of heat generating elements arranged in an array in a main scanning direction, and a thermosensitive medium moveable relative to said thermal head in a subscanning direction perpendicular to the main scanning direction while pressing said thermosensitive medium against said thermal head so as to cause said plurality of heat generating elements to repeatedly generate heat in accordance with an image signal, said method comprising:sensing an ambient temperature around the thermal head; detecting a print ratio in terms of a number of heat generating elements to be energized at the same time; and correcting an amount of heat to be generated by the thermal head on the basis of the ambient temperature sensed and the print ratio data output during master making operation so as to control print quality.
Priority Claims (1)
Number Date Country Kind
2000-106732 Apr 2000 JP
US Referenced Citations (4)
Number Name Date Kind
5685222 Yokoyama et al. Nov 1997 A
5690437 Yanagisawa et al. Nov 1997 A
5809879 Yokoyama et al. Sep 1998 A
6130697 Yokoyama et al. Oct 2000 A
Foreign Referenced Citations (5)
Number Date Country
2 277 904 Nov 1994 GB
2 294 906 May 1996 GB
8-90746 Apr 1996 JP
08-090746 Sep 1996 JP
11-115145 Apr 1999 JP