The present invention relates generally to thermal printing devices. More specifically, the present invention relates to a thermal printing head having a two-dimensional array of resistive heating elements, and a method of printing using such a thermal printing head.
Thermal printing heads used in imaging applications typically comprise a row of resistive heating elements extending across the entire width of the image to be printed. An image is formed by heating an imaging member while it is being transported in a direction perpendicular to the row of resistive heating elements on the print head. Pulses of heat are provided by supplying electrical current to the resistive heating elements. Each resistive heating element is individually addressable, such that any combination of pixels may be printed in a given line of the image. In some embodiments, the width of the thermal printing head may be less than the width of the image. In such cases the thermal printing head may be translated relative to the thermal imaging member in order to address the entire width of the image, or else more than one thermal printing head may be used.
Although the majority of commercially-available thermal printing heads have only a single row of resistive heating elements, thermal printing heads having a two-dimensional array of resistive heating elements (i.e., more than one line of resistive heating elements) are known in the art. For example, Japanese Patent Nos. JP-7290744 and JP-63084948 disclose thermal printing heads having two rows of resistive heating elements, each row being separately addressable. Japanese Patent No. JP-6206324 discloses a two-dimensional matrix of resistive heating elements comprising a plane of resistive heating elements located between a plane of row electrodes and a plane of column electrodes. A similar arrangement is disclosed in Japanese Patent No. JP-4358849. Japanese Patent No. JP-6278295 discloses a thermal printing head having two rows of resistive heating elements, in which the substrates for each row of resistive heating elements are not parallel to one another. Japanese Patent No. JP-9314881 discloses a thermal printing head having a single row of resistive heating elements in which the resistances of each resistive heating element in the row are not the same.
One object of the present invention is to provide a method for forming an image by heating a thermal imaging member with a single thermal printing head having more than one row of resistive heating elements, in which a first color is addressed by a row of resistive heating elements that is not used to address a second color.
Another object is to provide a method for forming an image by heating a thermal imaging member with a thermal printing head having more than one row of resistive heating elements, in which the method of supplying electrical power to a first row of resistive heating elements is not the same as the method of supplying electrical power to a second row of resistive heating elements.
Yet another object of the present invention is to provide a printing head comprising more than one row of resistive heating elements, in which the number of resistive heating elements per unit length in a first and second row of resistive heating elements is the same, and the resistance of any one resistive heating element in a first row is substantially different from the resistance of the corresponding resistive heating element in a second row.
Yet another object of the present invention is to provide a printing head comprising more than one row of resistive heating elements, in which the average resistance of the resistive heating elements in a first row is different from the average resistance of the resistive heating elements in a second row by a factor of at least about 1.5.
Yet another object is to provide a printing head comprising more than one row of resistive heating elements in which one row of resistive heating elements comprises elements that are a different shape from the resistive heating elements in a second row.
Yet another object of the present invention is to provide a printing head comprising more than one row of resistive heating elements, in which the number of resistive heating elements per unit length across a first row is substantially different from the number of resistive heating elements per unit length across a second row.
Additional objects, features, and advantages of the present invention will become apparent from the following detailed description of the preferred embodiments of the invention in conjunction with the accompanying drawings where like reference numerals indicate like features, in which:
Although electrical switches are indicated in the diagrams with the conventional symbol for mechanical switches, it will be understood by those skilled in the art that they may be any type of switching device, including transistors, FET's or other semiconductor devices.
Thermal printing heads are typically used to address imaging members of two general types: 1) those that rely on thermal transfer, in which heat is used to move a colorant from a donor to a receiver sheet, and 2) direct thermal systems, in which heat is used to convert a colorless composition arranged on a substrate into a colored form. The direct thermal method requires only a single sheet, and is the preferred approach from the standpoint of system cost and complexity. U.S. Pat. No. 6,801,233 B2 describes a single-sheet, direct thermal imaging member with which any color may be rendered simply by heating, preferably in a single printing pass with a single print head. The imaging member is stable before and after printing, and insensitive to normal room light. As shown in
Referring now to
Each image-forming layer can change color, e.g., from initially colorless to colored, where it is heated to a particular temperature referred to herein as its activating temperature. Spacer layer 20 is preferably thinner than spacer layer 22, provided that the materials comprising both layers have substantially the same thermal diffusivity. The function of the spacer layers is to control thermal diffusion within the imaging member 10.
All the layers disposed on the substrate 12 are substantially transparent before color formation. When the substrate 12 is reflective (e.g., white), the colored image formed on imaging member 10 is viewed through the overcoat 24 against the reflecting background provided by the substrate 12. The transparency of the layers disposed on the substrate ensures that combinations of the colors printed in each of the image-forming layers may be viewed.
Each of the image-forming layers 14, 16 and 18 is independently addressed by application of heat using a thermal printing head in contact with the topmost layer of the member, usually optional overcoat layer 24 in the member illustrated in
The heating of the lower image-forming layers, i.e., those closer to the substrate 12, is accomplished by maintaining the thermal printing head at temperatures such that the upper image-forming layer(s) remain below their activating temperatures for sufficient periods of time to allow heat to diffuse through them to reach the lower image-forming layer(s). In this way, no image information is provided in the upper image-forming layer(s) when the lower image-forming layer(s) are being imaged. The heating of the image-forming layers according to the method of the invention may be accomplished by one or more than one pass of a single thermal printing head, or by one or more than one pass of each of more than one thermal printing head, as is described in detail below.
Control of two independent variables available in a thermal printer, namely, the power that is supplied to the resistive heating elements of the thermal print head, and the length of time during which that power is supplied, allow the independent addressing of each of the color-forming layers of an imaging member such as that shown in
Although
The precise shape of the printing regions in practice will not, of course, be rectangular as shown in
Referring now to
The support 13 provides mechanical strength to the printing head so that it may be easily affixed to the chassis of the printer and biased against the thermal imaging member. Support 13 may also function as a heat sink, and is commonly made of a material of high thermal conductivity, such as aluminum. Support 15 may be provided with cooling fins for air cooling, or channels for liquid cooling, as described above. The temperature of support 13 may be monitored (by means, for example, of a thermistor), and knowledge of this temperature may be used to adjust the energy that is provided to the heating elements for optimal imaging, as is known in the art and described, for example, in U.S. Pat. No. 6,819,347.
Because conventional direct thermal or thermal transfer imaging members require heating to form only a single color, design of thermal printing heads for addressing such imaging members has remained fairly straightforward. The motivation for incorporation of more than one row of resistive heating elements in prior art thermal printing heads has been, for example, to increase the resolution of the thermal printing head or to increase the speed of printing by addressing more than one line at a time.
As described above, however, in addressing a multicolored direct thermal imaging medium of the type shown in
Another difficulty arises when addressing more than one color in a multicolor direct thermal imaging member in a single pass of a thermal printing head having only a single row of resistive heating elements. In such a case, the time available for printing a given line must be shared between the different colors (i.e., all of the different color-forming layers of the thermal imaging member must be addressable within the time available for printing a single line). In practice, this means that printing of at least one color may be less than optimal. In particular, when printing the color with the highest activation temperature and the color with the lowest activation temperature together, ideally none of any color having an intermediate activation temperature should be printed. When these two colors are printed almost simultaneously within a single line time, this may be difficult to achieve. It becomes much easier to avoid undesired coloration of an intermediate-temperature color if there is a delay between printing the highest-temperature color and printing the lowest-temperature color. Such a delay may be achieved by a spatial offset between rows of resistive heating elements of a thermal printing head having more than one row of such elements.
Therefore, one preferred method of the present invention is addressing a multicolored direct thermal imaging member with a single thermal printing head in a single pass, in which a first color is addressed by a row of resistive heating elements that is not used to address a second color. For example, a first row could be used to address the highest-temperature color, and a second row could be used to address the lowest-temperature color. The intermediate-temperature color or colors could be addressed by either row, or else by yet another row of resistive heating elements.
When the thermal printing head contains more than one row of resistive heating elements, the addressing of more than one color by variation of power and time of heating may become more straightforward than if the printing head has only a single row of resistive heating elements. For example, a higher voltage may be applied to a first row of resistive heating elements than to a second row. The first row will provide a higher power than the second row, and may be used to form an image in a color requiring high power and short time. The second row may be used to form an image in the color requiring a low power and a long time.
More generally, an object of the present invention is to provide a method for forming an image by heating a thermal imaging member with a thermal printing head having more than one row of resistive heating elements, in which the method of supplying electrical power to a first row of resistive heating elements is not the same as the method of supplying electrical power to a second row of resistive heating elements. As mentioned above, a different voltage may be applied to a first than to a second row of resistive heating elements. Likewise, a different duty cycle of pulsing may be applied when printing with a first row of resistive heating elements than when printing with a second row. It is also possible that a different dot screening pattern might be used for printing with a first row of resistive heating elements than for printing with a second row. In addition, different dot placement (i.e., “phasing” as described below) may be used for printing with a first row of resistive heating elements than for printing with a second row.
The purpose of phasing is to minimize the peak power that must be supplied to a row of resistive heating elements (i.e., to provide load leveling). When the imaging is carried out in a single pass of the thermal printing head, the speed of transport of the imaging member past a first and a second row of resistive heating elements is the same. However, as mentioned above, the time of heating required when printing a color requiring a high power is shorter than the time required when printing a color requiring a relatively low power. In the case where a first row of resistive heating elements is used to form an image in a color-forming layer of the thermal imaging member requiring relatively high power, and a second row of resistive heating elements is used to form an image in a color-forming layer requiring the relatively low power, the time during which power must be supplied to a resistive heating element in the first row will typically be shorter than the time during which power must be supplied to the corresponding resistive heating element in the second row. To maintain a low peak power requirement when printing with all the elements in the first row, it may be preferred not to address every element in that row at the same time. The ratio of the time required for heating of an element in the second row to the time required for heating of an element in the first row (n, say) gives the maximum number of groups into which the resistive heating elements in the first row may be divided such that each resistive heating element in a group is heated simultaneously, no element in one group is heated while any element in another group is being heated, and all elements in the first row are heated during the time required for printing using the second row. Since the heating of each group of elements in the first row is temporally offset from the heating of the other groups, the maximum number of “phases” of the heating cycle when addressing the entire first row is “n”, and this method of addressing of the line of resistive heating elements is known as “phasing”. The peak power for printing with the first row of resistive heating elements is not given by the peak power for one element in the row multiplied by the total number of elements in that row, but rather is given by this quantity divided by “n”.
Thus, one preferred method of the present invention comprises heating a multicolor direct thermal imaging member with a thermal printing head having more than one row of resistive heating elements, in which the phasing of the addressing of a first row of resistive heating elements is not the same as the phasing of the addressing of a second row of resistive heating elements.
Another object of the present invention is to provide a method for forming an image by heating a thermal imaging member with a thermal printing head having more than one row of resistive heating elements, in which a correction(s) that is/are applied to the image printed by one row of resistive heating elements is/are different from a correction(s) that is/are applied to the image printed by a second row of resistive heating elements.
In the practice of the present invention, it is preferred that the printing pulses supplied by the thermal printing head be adjusted so as to compensate for the residual heat in the printing head itself and in the thermal imaging member that results from the printing of preceding (and neighboring) pixels in the image. Such thermal history compensation may be carried out as described in U.S. Pat. No. 6,819,347 B2. It is usual that the thermal history compensation required for a first row of resistive heating elements in a thermal printing head having more than one row of resistive heating elements will be different from the thermal history compensation required for a second row. For example, one row may encounter the thermal imaging member when the member is at ambient temperature, but a second row may encounter the thermal imaging member shortly after the member has been heated by the first row.
Another correction that may be different for one row of resistive heating elements than for another is a voltage correction such as that described in U.S. Pat. No. 6,661,443 B2. This correction ensures that the same amount of thermal energy is provided by a resistive heating element in a particular row intended to produce a particular color regardless of the number of resistive heating elements in that row that are active at the time of printing.
Yet another correction that may be different for one row of resistive heating elements than for another is the correction for streaks in the image in the direction of transport of the imaging member. Such streaks may arise from non-uniformities in the thermal printing head, such that each resistive heating element does not provide exactly the same amount of thermal energy to the imaging member even though all resistive heating elements are intended to do so. There are many possible sources of such non-uniformity, for example, non-uniform resistance of the resistive heating elements, or lack of uniform thickness of any glaze or protective layers comprising the thermal printing head.
Using a thermal printing head having more than one row of resistive heating elements provides additional flexibility in controlling the power supplied in order to select a particular color as is required in the printing methods of the present invention. For example, the resistance of each resistive heating element in a row that addresses one color may be different from the resistance of each resistive heating element in a row that addresses a second color. Neither the voltage nor the duty cycle of pulsing need be different for addressing of each color (although in practice some adjustment may be needed) since the power dissipated in the resistive heating elements will be controlled by their resistance (and equal to Vˆ2/R).
One preferred printing head of the present invention comprises more than one row of resistive heating elements, in which the average resistance of the resistive heating elements in a first row is different from the average resistance of the resistive heating elements in a second row by a factor of at least about 1.5.
A particularly preferred printing head of the present invention comprises more than one row of resistive heating elements, in which the resistance of each of the resistive heating elements in a particular row is substantially the same, and the resistance of the each of the resistive heating elements in a first row is substantially different from the resistance of each of the resistive heating elements in a second row.
It is not necessary that the resistance of each resistive heating element in a particular row be the same, although in practice it is certainly easier to manufacture thermal printing heads of this type. In another type of preferred thermal printing head of the present invention comprising more than one row of heating elements, the number of resistive heating elements per unit length across a first and second row of resistive heating elements is the same, and the resistance of any one resistive heating element in a first row is substantially different from the resistance of the corresponding resistive heating element in a second row.
As mentioned above, control of the heating time for a particular color-forming layer is required as well as control of the power supplied. The longer a resistive heating element extends in the direction of transport of the imaging member, the longer can be the heating time for a given rate of transport of the imaging member. For a color-forming layer that is addressed at a low temperature and for a long time, therefore, a long resistive heating element in the transport direction may be preferred. For a color-forming layer that is addressed at a high temperature (i.e., high power) for a short time, on the other hand, a resistive heating element with a large area may require an impracticably large current to be supplied. It may be preferred for this layer to be addressed with a shorter resistive heating element and more frequent heating pulses. A preferred thermal printing head of the present invention comprises more than one row of resistive heating elements, in which one row of resistive heating elements comprises elements that are of a different shape than the resistive heating elements in a second row.
A particularly preferred thermal printing head of the present invention comprises more than one row of resistive heating elements, in which a first row of resistive heating elements comprises elements that are longer, as measured in the direction perpendicular to the row, than the resistive heating elements in a second row.
Another object of the present invention is to provide a printing head comprising more than one row of resistive heating elements, in which the number of resistive heating elements per unit length across a first row is substantially different from the number of resistive heating elements per unit length across a second row. Such a second row might, for example, be used to print an image in black text. In an extreme case, one row may comprise only a single resistive heating element, and this resistive heating element may be used to provide pre-heating or post-heating of the thermal imaging member. Alternatively, such a single element may be used to provide a “background color” to an image that is printed by a multi-element, second row. Using such a printing head in combination with a thermal imaging member 10, differently colored labels bearing monochrome text would readily be printed.
As described in U.S. patent application Ser. Nos. 11/400,735 and 11/400,734, both filed on Apr. 6, 2006, the amount of heat that must be supplied to a multicolored direct thermal imaging member may be significantly affected by the temperature of the thermal imaging member at the time of heating. Adjustment of the starting temperature of a particular color-forming layer (hereinafter referred to as the “baseline temperature” of that layer) may be achieved through pre-heating of the thermal imaging member. The color-forming layers with the lowest activation temperatures are affected differently by preheating than color-forming layers with higher activation temperatures. It may be preferred to preheat the medium before printing the color-forming layers with low activation temperatures but not before printing the color-forming layers with higher activation temperatures. When a thermal printing head with more than one row of resistive heating elements is used to form an image in a multicolored direct thermal imaging member, it may therefore be advantageous if there also is provided, in between the two rows of resistive heating elements, a single resistive heating element extending across the entire width of the thermal printing head that is used to pre-heat the thermal imaging member.
The matter of addressing more than one row of individual resistive heating elements may be solved in a variety of ways, some of which are known in the art. For example, the methods of Japanese Patent Nos. JP-7290744, JP-63084948 and JP-6206324 discussed above may be employed. There are also some methods for addressing more than one row of resistive heating elements that have not hitherto been described that may be advantageous in the practice of the present invention.
In ideal addressing of more than one row of resistive heating elements, each resistive heating element in each row would be independently addressable at the same time. In the current state of manufacturing art, each switchable electrode must be connected to driving circuitry, and this connection is typically made via a wire bond. It is preferred that all wire bonds be made on the same side of the array of resistive heating elements, since the cost of assembly is higher when wire bonds have to be made on both sides of the array. Finally, it is preferred that the electrodes all be located in the same plane, or on the same surface. It is possible that multiple planes of electrodes or connectors may be employed, as discussed below, but this adds to the cost of the thermal printing head.
A brief discussion of prior art methods of addressing a single row of resistive heating elements will now be given, since each method has geometrical consequences that affect how electrical connections may be made in a two-dimensional array of resistive heating elements.
A typical resistive heating element used in the art is made by depositing a thin layer of a resistive material between two opposing electrodes made of a highly conductive material. The process of deposition may be sputtering in a vacuum (producing what is known in the art as a “thin film” resistive heating element) or a liquid deposition process (producing what is known in the art as a “thick film” resistive heating element). The precision of the former process is generally greater than that of the latter. Either process may be used to fabricate thermal printing heads of the present invention. Other approaches may also be employed. It is generally preferred that the current passing through the resistive heating element travel substantially in the plane of the substrate on which the resistive heating element is deposited. There are thus two dimensions in which the current may be designed to travel: substantially parallel to the row of resistive heating elements, and substantially perpendicular to the row. Corresponding to these two directions, the opposing electrodes are arranged either substantially perpendicular or substantially parallel, respectively, to the row of resistive heating elements.
In practice, for reasons of ease of manufacturing, a design such as that shown in
The resistive heating elements and electrodes of the preferred thermal printing heads of the present invention discussed above with reference to
Any method of switching (i.e., addressing) the individual resistive heating elements may be used that is consistent with the basic architecture outlined schematically in
Although the invention has been described in detail with respect to various preferred embodiments, it is not intended to be limited thereto, but rather those skilled in the art will recognize that variations and modifications are possible which are within the spirit of the invention and the scope of the appended claims.
This application claims the benefit of prior provisional patent application Ser. No. 60/734,081, filed Nov. 7, 2005. This application is related to the following commonly assigned, United States patent applications and patents, the entire disclosures of which are hereby incorporated by reference herein in their entirety: U.S. Pat. No. 6,801,233 B2; U.S. Pat. No. 6,906,735 B2; U.S. Pat. No. 6,951,952 B2; U.S. Pat. No. 7,008,759 B2; U.S. patent application Ser. No. 10/806,749, filed Mar. 23, 2004, which is a division of U.S. Pat. No. 6,801,233 B2; U.S. patent application Ser. No. 10/374,847, filed Feb. 25, 2003; U.S. patent application Ser. No. 10/789,648, filed Feb. 27, 2004; U.S. patent application Ser. No. 10/789,566, filed Feb. 27, 2004; U.S. patent application Ser. No. 10/789,600, filed Feb. 27, 2004; U.S. patent application Ser. No. 11/159,880, filed Jun. 23, 2005; U.S. patent application Ser. No. 11/400,734, filed Apr. 6, 2006; U.S. patent application Ser. No. 11/400,735, filed Apr. 6, 2006; and U.S. patent application Ser. No. 60/734,081, filed Sep. 20, 2006.
Number | Date | Country | |
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60734081 | Nov 2005 | US |