FIELD OF THE INVENTION
The present invention relates to thermal printers and more specifically, to controlling the heating of a thermal printhead based on temperatures measured at the thermal printhead and away from the thermal printhead.
BACKGROUND
A typical thermal printhead uses a temperature sensor (e.g., thermistor) integrated with the thermal printhead to measure a printhead temperature. The printhead temperature is used to control the energy applied to the thermal printhead for heating during printing. For example, as the thermal printhead becomes hot during printing, the energy applied to the thermal printhead may be reduced. Reducing the heating, however, may affect print quality, especially if the print medium (e.g., thermal paper) is cold (e.g., in a cold environment).
To insure high-quality thermal printing, both the temperature of the printhead and the temperature of the environment should be used for print-temperature control. In this way, when the printhead temperature and the environment temperature diverge, the heating of the thermal printhead may be compensated so that the print quality does not suffer.
Therefore, a need exists for a thermal printer that monitors both a printhead temperature and an environment temperature and that can adapt its heating to maintain print quality when the printhead temperature and the environment temperature differ.
SUMMARY
Accordingly, in one aspect, the present invention embraces a thermal printer. The thermal printer includes a thermal printhead with an array of heating elements that are positioned close to a print-medium path. A print-medium subsystem is also included as part of the thermal printer. The print-medium path includes a spool for holding a print medium and a movement mechanism for moving the print medium off the spool and along the print-medium path so that the print medium may be heated by the array of heating elements. The thermal printer also includes a housing to contain/support the thermal printhead and the print-medium subsystem and two sensors (a printhead sensor and an environment sensor) to measure temperature. Both sensors are contained in the housing. The first sensor (e.g., a printhead sensor) is contiguous to the thermal printhead and measures a printhead temperature. The second sensor (e.g., an environment sensor) is positioned apart from the thermal printhead and measures an environment temperature. A processor, also contained in the housing, is communicatively coupled to the thermal printhead, the printhead sensor, and the environment sensor. The processor is configured by software to compare the environment temperature and the printhead temperature. The processor is further configured to compute a temperature value (e.g., a compensated temperature) based on the comparison, and to control the heating of the array of heating elements using the temperature value.
In an exemplary embodiment of the thermal printer, the control of the heating of the array of heating elements includes adjusting the energy applied to the heating elements to minimize the difference between the compensated temperature and a set-point temperature. In one possible embodiment, the set-point temperature corresponds to characteristics of the print-medium subsystem and the print medium. For example, the characteristics of the print medium subsystem and the print medium include the speed at which the print medium moves along the print-medium path and/or the thermal sensitivity of the print medium.
In another exemplary embodiment of the thermal printer, the environment sensor is positioned proximate to the spool.
In another exemplary embodiment of the thermal printer, the environment temperature is approximately the temperature of the print medium.
In another exemplary embodiment of the thermal printer, the print medium is thermal paper.
In another exemplary embodiment of the thermal printer, the printhead sensor and the environment sensor are thermistors.
In another exemplary embodiment, comparing the environment temperature to the printhead temperature includes calculating a temperature gap, which is the difference between the environment temperature and the printhead temperature. For the case in which the temperature gap is below a temperature-gap threshold, the processor is configured to compute a compensated temperature by using the printhead temperature as the compensated temperature. For the case in which (i) the temperature gap is above a temperature-gap threshold and (ii) the environment temperature is greater than the printhead temperature, the processor is configured to compute a compensated temperature by adding a compensation value to the printhead temperature. For the case in which (i) the temperature gap is above a temperature-gap threshold and (ii) the environment temperature is less than the printhead temperature, the processor is configured to compute a compensated temperature by subtracting a compensation value from the printhead temperature.
In another aspect, the present invention embraces a print-temperature control system for a thermal printer. The system includes a printhead sensor that is mounted on the thermal printer's printhead and an environment sensor mounted away from the printhead. The printhead sensor measures a printhead temperature and the environment sensor measures an environment temperature. The system also includes a processor that is communicatively coupled to the printhead sensor and the environment sensor. The processor is configured by software to compare the environment temperature and the printhead temperature. Based on this comparison, the processor is configured to create a compensated temperature, and to use this compensated temperature to adjust the energy applied to the thermal printer's printhead.
In an exemplary embodiment of the print-temperature control system, the comparison of the environment temperature to the printhead temperature includes computing a temperature gap, which is the difference between the environment temperature and the printhead temperature.
In one possible embodiment of the print-temperature control system, the compensated temperature is computed to equal the printhead temperature if the temperature gap is below a temperature-gap threshold.
In another possible embodiment of the print-temperature control system, the compensated temperature is computed to not equal the printhead temperature if the temperature gap is above a temperature-gap threshold. For the case in which (i) the temperature gap is above a threshold temperature and (ii) the environment temperature is greater than the printhead temperature, then, in one possible embodiment, the compensated temperature is computed to be greater than the printhead temperature. For the case in which (i) the temperature gap is above a threshold temperature and (ii) the environment temperature is less than the printhead temperature, then, in one possible embodiment, the compensated temperature is computed to be less than the printhead temperature.
In another aspect, the present invention embraces a method for controlling the print temperature of a thermal printhead. The method includes providing a thermal printer. The thermal printer includes (i) a thermal printhead to heat thermal paper, (ii) a printhead thermistor to measure a printhead temperature, which corresponds to the temperature of the printhead, and (iii) an environment thermistor to measure an environment temperature, which corresponds to the temperature of the thermal paper. The method also includes the step of measuring the printhead temperature and the environment temperature and the step of comparing the two temperatures to create a compensated temperature. Finally, the method includes the step of controlling the heating of the thermal printhead using the compensated temperature.
In one possible embodiment of the method, the method further includes the steps of measuring the difference between the environment temperature and the printhead temperature and determining if the environment temperature is greater than or less than the printhead temperature.
The foregoing illustrative summary, as well as other exemplary objectives and/or advantages of the invention, and the manner in which the same are accomplished, are further explained within the following detailed description and its accompanying drawings.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 depicts a side view of a thermal printhead according to an exemplary embodiment of the present invention.
FIG. 2 depicts a perspective view of a thermal printer with a portion of the housing removed according to an exemplary embodiment of the present invention.
FIG. 3 depicts a flow diagram of the thermal control of a thermal printhead according to an exemplary embodiment of the present invention.
FIG. 4 depicts a flow diagram of a method for controlling the heating of a thermal printhead according to an exemplary embodiment of the present invention.
DETAILED DESCRIPTION
Direct thermal printing (i.e., thermal printing) is a printing process, wherein a printed mark is produced by selectively heating a print medium (e.g., thermal paper). When heated above a thermal threshold, chemicals coating the print medium change color to form a mark. To ensure good print quality, it is important to selectively heat regions on the print medium above a thermal threshold but not so high as to cause neighboring regions to change color as well.
A thermal printer uses a thermal printhead (i.e., printhead) for heating. An exemplary thermal printhead is shown in FIG. 1 (i.e., FIG. 1). The thermal printhead 1 includes an array of heating elements (i.e., dots) 2. The dots may be arranged in a 2D array or a linear array (i.e., a line), and an electric current may be applied to each dot to generate heat. By moving a print medium 3 past the dots 2 (i.e., along a print-medium path shown by arrows in FIG. 1), marks may be created on the print medium 3 by selectively heating the dots in a pattern that corresponds to a line of printing. In this way letters, numbers, and/or images (e.g., barcodes) may be formed line-by-line on the print medium as the print medium moves past the heating elements 2.
It is important for print quality to control the timing of the heating/cooling of the heating elements to match the speed at which the print medium 3 moves. It is also important for print quality to control the energy applied to heat/cool the heating elements. The array of heating elements 2 may be cooled through the use of a heat sink. The heat sink insures that the heating elements are cooled sufficiently from one line of printing to the next. In some situations (e.g., fast printing, heavy printing, frequent printing, hot environments, etc.) the heat sink may not cool the heating elements 2 sufficiently. Rather than slowing or stopping the printing process to cool the heating elements 2, it is customary to adjust the energy applied to the heating elements to compensate for the increase in printhead temperature. As a result, a sensor (e.g., thermistor) is typically attached contiguously to (e.g., integrated with) the thermal printhead 1 to measure a printhead temperature. The measured printhead temperature may then be used as feedback to control the heating of the thermal printhead.
A thermal printer may also include a print-medium subsystem for holding/storing unused print medium and moving the print medium past the thermal printhead and out of the thermal printer. FIG. 2 illustrates a perspective view of a thermal printer 6 with a portion of the housing removed to show the print-medium subsystem. The print-medium subsystem may include a spool (or spindle) 7 for holding the print medium 3. The print-medium subsystem also includes a movement mechanism for moving the print medium off the spool 7 and along a print medium path. The movement mechanism may include components to direct or tension the print medium (e.g., rollers, tensioners, etc.). These components may be powered (directly or indirectly) with motors to exert force (e.g., fiction force) on the print medium and move it along the print-medium path. A platen roller 4 is typically included to insure that the print medium 3 is brought into close proximity with the array of heating elements 2. The platen roller 4 may also help move the print medium.
As mentioned previous, the energy applied to a thermal printhead's heating elements can be controlled to prevent overheating or under-heating the print medium. In addition, the control of the thermal printhead's heating is typically accomplished through the use of a temperature sensor (i.e., a printhead sensor 5) mounted directly to the thermal printhead. Using a printhead sensor 5 by itself, however, does not account for the temperature of the print medium.
The temperature of the print medium may affect print quality when there is a large difference (i.e., temperature gap) between the thermal printhead's temperature and the print-medium's temperature. For example, if the printhead is hot and the print medium is cold, then reducing the heating of the printhead may cause printing errors, since a cold print medium may require substantial energy to raise the print medium's temperature above the thermal threshold necessary for printing. Likewise, if the print medium is hot and the printhead is cold, then increasing the heating of the printhead may cause printing errors, since additional energy applied to a hot print medium may cause unwanted marks, blurred characters, and/or shading.
To address the problem described, an additional temperature sensor (i.e., environment sensor 8) may be positioned inside the thermal printer's housing to measure an environment temperature that closely corresponds to the print-medium temperature. The environment sensor 8 is typically positioned close to the print medium 2 (e.g., spaced less than 2.5 centimeters from the spool 7) and apart (e.g., spaced greater than 2.5 centimeters) from the thermal printhead 1 so that the temperature of the printhead does not substantially affect the measured environment-temperature. In this way, the measured environment-temperature is approximately (e.g., ±2.5 degrees Celsius) the temperature of the print medium.
The present invention embraces using two temperature sensors: a printhead sensor 5 contiguous to the thermal printhead 1 to monitor the temperature of the thermal printhead and an environment sensor 8 position away from the thermal printhead 1 to monitor the temperature of the environment (i.e., the approximate temperature of the print medium). In this way, the control of the heating of the thermal printhead for printing may be adjusted to compensate for differences (i.e., gaps) between the two sensed temperatures.
A flow diagram of an exemplary thermal (i.e., print temperature) control system embraced by the present invention is shown in FIG. 3. A set-point temperature 10 is established based on the printing conditions. Some printing conditions include (but are not limited to) the speed that the print medium moves along the print-medium path (i.e., print speed), the print-medium's type, the sensitivity (i.e., thermal threshold) of the print medium, the heat sink properties, and the dot resistance. This set-point temperature may be stored in memory based (e.g., during fabrication) or based on settings adjusted by a user. A processor 11 compares a sensed temperature to the set-point temperature 10 (e.g., recalled from memory), and then based on this comparison, adjusts the energy (e.g., current, duty cycle, etc.) applied to the thermal print head 1 (i.e., the thermal-printhead's heating elements) to minimize any difference. Typically, the sensed temperature is the printhead temperature, but as shown in FIG. 3, the present invention embraces creating a compensated temperature 12 for feedback. The compensated temperature compensates for a difference between the printhead temperature 13 and the environment temperature 14 that could otherwise lead to printing errors (i.e., low quality printing).
FIG. 4 depicts a flow diagram of a method for controlling the heating of a thermal printhead using a compensated temperature. The temperature of the thermal print head is measured with a printhead sensor 20, and the temperature of the environment is measured with an environment sensor 25. A processor (configured by software) then computes a temperature gap based on the difference between the printhead temperature and the environment temperature. The processor compares the temperature gap to a temperature-gap threshold 30 (e.g., 10 degrees Celsius). If the temperature gap does not exceed the threshold (i.e., the printhead temperature and the print-medium temperature are similar), then the printhead temperature may be used as feedback to control the heating of the thermal printhead 35. In other words, a compensated temperature is created that equals the printhead temperature. If the temperature-gap threshold is exceeded, however, the processor compares the printhead temperature to the environment temperature to determine which temperature is higher 40. If the environment temperature is greater than the printhead temperature, then the processor computes a compensated temperature that is greater than the printhead temperature 45. If the environment temperature is less than the printhead temperature, then the processor computes a compensated temperature that is less than the printhead temperature 50. The compensated temperature is used as feedback to control the heating of the printhead's heating elements 55.
The computation of the compensated temperature may include adding or subtracting a compensation value to the printhead temperature. The compensation value may not equal the temperature gap but typically, the compensation value has a magnitude that corresponds to the temperature gap.
As illustrated in FIG. 3, when the compensated temperature 12 is less than the set-point temperature 10, more heating is applied to the thermal printhead's heating elements. Alternatively, when the compensated temperature 12 is greater than the set-point temperature 10, less heating is applied to the thermal printhead's heating elements.
While compensated temperature has been shown to facilitate thermal control, compensated temperature may also be used to control other characteristics that affect print quality. These other characteristics may include (but are not limited to) print speed, print-head pressure, and/or set-point temperature. In addition, the detection of a large temperature gap may indicate a problem with the thermal printer. In this case, the processor may be configured to initiate other actions. These actions may include (but are not limited to) generating an error message, generating a diagnostic message, and/or halting the printing process.
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In the specification and/or figures, typical embodiments of the invention have been disclosed. The present invention is not limited to such exemplary embodiments. The use of the term “and/or” includes any and all combinations of one or more of the associated listed items. The figures are schematic representations and so are not necessarily drawn to scale. Unless otherwise noted, specific terms have been used in a generic and descriptive sense and not for purposes of limitation.