Patent Application
20100026776
The present invention relates to thermal printers of type that apply material from a donor web to a receiver web in order to form images on the receiver web.
In thermal printing, it is generally well known to render images by heating and pressing one or more donor materials such as a dye, colorant or other coating against a receiver web. The donor materials are provided in sized donor patches on a movable web known as a donor ribbon. The donor patches are organized on the ribbon into donor sets; each set containing all of the donor patches that are to be used to record an image on the receiver web. For full color images, multiple color dye patches can be used, such as yellow, magenta, and cyan donor dye patches. Arrangements of other color patches can be used in like fashion within a donor set. Additionally, each donor set can include an overcoat or sealant layer.
Thermal printers offer a wide range of advantages in photographic printing including the provision of truly continuous tone scale variation and the ability to deposit, as a part of the printing process a protective overcoat layer to protect the images formed thereby from mechanical and environmental damage. Accordingly, the most popular photographic kiosks and home photo printers currently use thermal printing technology.
Electrostatic charge can be generated in thermal printers by peeling donor media from receiver media. Electrostatic charge is a significant concern and problem for makers of thermal printers, because excess static charge leads to jamming and buckling of print media as the print media traverses through the thermal printer. Conventional approaches to addressing static charge focus on the media itself in that, ionic or nonionic anti-stats are added to the media; for example, the receiver media. This anti-static material is adjusted positionally to reduce static charge. In other words, the anti-static material may be placed in multiple locations with varying effectiveness. The anti-stats may be placed in various layers of the receiver and donor media.
Limitations of anti-stats include, for ionic anti-stats, their ineffectiveness in high humidity. Both ionic and non-ionic anti-stats are subject to great expense, and imprecise usage that is dependent upon the receiver media impacted with reduction of static charge. Another disadvantage associated with non-ionic anti-stats is an addition of unwanted color in white areas of a print.
A thermal printer having reduced electrical charge built at point of separation of a donor web and a receiver web, includes at least one thermal printhead and at least one platen roller with a nip formed between the at least one thermal printhead and the at least one platen roller through which the donor web and the receiver web are drawn. A heat sink is attached to the at least one thermal printhead and a peel member is located downstream of the nip. The peel member is electrically isolated from ground.
Another aspect of the invention provides a method for eliminating built-up electrical static charge in a thermally conductive peel member assembly that includes electrically isolating the thermal conductive peel member from ground, while maintaining the thermal conductive peel member's physical proximate contact with a heat sink assembly of a thermal printhead.
Thermal resistors 43 are adapted to generate heat in proportion to an amount of electrical energy that passes through thermal resistors 43. During printing, controller 20 transmits signals to a circuit board 51 to which thermal resistors 43 are connected causing different amounts of electrical energy to be applied to thermal resistors 43 so as to selectively heat donor web 30 in a manner that is intended to cause donor material from donor patches 34, 36, 38, and 40 to be applied to receiver web 26 in a desirable manner.
As is shown in
A first color is printed in the conventional direction, from right to left as seen by the viewer in
Controller 20 also actuates receiver web take-up roller 42 and receiver web supply roller 44 so that image receiving area 52 of receiver web 26 is positioned with respect to the thermal printhead 22. In the embodiment illustrated, image receiving area 52 is defined by a leading edge LER and a trailing edge TER on receiver web 26. Donor web 30 and receiver web 26 are positioned so that leading edge LED of yellow donor patch 34.1 is registered at thermal printhead 22 with leading edge LER of image receiving area 52. Controller 20 then causes a motor or other conventional structure (not shown) to lower thermal printhead 22 so that a lower surface of donor web 30 engages receiver web 26 which is supported by platen roller 46. This creates a pressure holding donor web 30 against receiver web 26.
Controller 20 then actuates receiver web take-up roller 42, receiver web supply roller 44, donor web take-up roller 48, and donor web supply roller 50 to move receiver web 26 and donor web 30 together past the thermal printhead 22. Concurrently, controller 20 selectively operates heater elements in thermal printhead 22 to transfer donor material yellow donor patch 34.1 to receiver web 26.
As donor web 30 and receiver web 26 leave the thermal printhead 22, a stripping plate 54 separates donor web 30 from receiver web 26. Donor web 30 continues over idler roller 56 toward the donor web take-up roller 48. As shown in
Controller 20 operates the printer 18 based upon input signals from a user input system 62, an output system 64, a memory 68, a communication system 74, and sensor system 80. User input system 62 can comprise any form of transducer or other device capable of receiving an input from a user and converting this input into a form that can be used by controller 20. For example, user input system 62 can comprise a touch screen input, a touch pad input, a 4-way switch, a 6-way switch, an 8-way switch, a stylus system, a trackball system, a joystick system, a voice recognition system, a gesture recognition system or other such systems. An output system 64, such as a display, is optionally provided and can be used by controller 20 to provide human perceptible signals for feedback, informational or other purposes.
Data including, but not limited to, control programs, digital images and metadata can also be stored in memory 68. Memory 68 can take many forms and can include without limitation conventional memory devices including solid state, magnetic, optical or other data storage devices. In the embodiment of
In the embodiment shown in
Sensor system 80 includes circuits and systems that are adapted to detect conditions within printer 18 and, optionally, in the environment surrounding printer 18 and to convert this information into a form that can be used by controller 20 in governing printing operations. Sensor system 80 can take a wide variety of forms depending on the type of media therein and the operating environment in which printer 18 is to be used.
In the embodiment of
During a full image printing operation, controller 20 causes donor web 30 to be advanced in a predetermined pattern of distances so as to cause a leading edge of each of the first donor patches 34.1, 36.1, 38.1, and 40.1 to be properly positioned relative to the image receiving area 52 at the start each printing process. Controller 20 can optionally be adapted to achieve such positioning by precise control of the movement of donor web 30 using a stepper type motor for motorizing donor web take-up roller 48 or donor web supply roller 50 or by using a movement sensor 86 that can detect movement of donor web 30. In one example, an arrangement using a receiver web position sensor 84, a follower wheel 88 is provided that engages donor web 30 and moves therewith. Follower wheel 88 can have surface features that are optically, magnetically or electronically sensed by movement sensor 86. One example of this is a follower wheel 88 that has markings thereon indicative of an extent of movement of donor web 30 and a movement sensor 86 that has a light sensor that can sense light reflected by the markings. In other optional embodiments, perforations, cutouts or other routine and detectable indicia can be incorporated onto donor web 30 in a manner that enables movement sensor 84 to provide an indication of the extent of movement of the donor web 30.
Alternatively, donor position sensor 82 can also optionally be adapted to sense the color of donor patches on donor web 30 and can provide color signals to controller 20. In this alternative, controller 20 is programmed or otherwise adapted to detect a color that is known to be found in the first donor patch, e.g., yellow donor patch 34.1 in a donor patch set such as first donor patch set 32.1. When the first color is detected, controller 20 can determine that donor web 30 is positioned proximate to the start of a donor patch set.
An exemplary thermal printer schematic 400, shown in
In
In
Peel member 470 can be a plate, a roller, or a bar. Alternatively, peel member 470 can be a combination of either—a plate, roller, or bar. Sources of resistance, that enable electrical isolation of peel member 470 from thermal printhead with heat sink 465 can include non-conductive tape and plastic washers.
Conventional wisdom, involving electrical current and electrical conductive material, states that the electrical conductive material should be grounded. Applicants' novel approach reduces transfer of electrostatic charge, because peel member 470 is at least substantially electrically isolated.
In sharp contrast to
A view of a triboelectric effect, as shown in
A prior-art multi-headed printer is illustrated in
Referring to
Each reloadable ribbon cassette assembly comprises a cassette body including a ribbon supply roll 1112a, 1114a or 1116a and a ribbon take-up roll 1112b, 1114b or 1116b. The ribbon cassette assemblies are loaded with one of three or more primary color ribbons 1112c, 1114c, and 1116c, which are used in conventional subtractive color printing. The supply and take-up rolls of each ribbon cassette assembly are coupled to individual ribbon drive sub-assemblies when the cassette assembly is loaded into the printer for printing images on the receiver. In addition to an assembly for each of the color ribbons, there may also be provided a ribbon cassette assembly 1118 that is provided with a supply of transparent ribbon 1118c that can transfer an overcoat layer to the receiver after an image has been printed thereon. The transparent ribbon cassette assembly is similar in all respects to the other assemblies (including supply and take-up rolls 1118a and 1118b), and a separate printhead is used to transfer the overcoat layer to the now imaged receiver. Different types of transparent ribbon may be used to provide matt or glossy finish overcoats to the final print. Alternatively, the printhead associated with the transparent ribbon may have the respective recording elements suitably modulated to create different finish overcoats to the final print.
Receiver 1111 having a coating thereon for receiving a thermal dye is supported as a continuous roll and threaded about platen rollers 1113a-d. The receiver is also threaded through a nip comprised of a capstan drive roller 1117 and a back-up roller 1117a. As the receiver is driven by the capstan drive roller the receiver passes by each thermal printhead assembly 1112, 1114, and 1116 a respective color dye image is transferred to the receiver sheet to form the multicolor image. For example, thermal printhead assembly 1112 may provide a yellow color separation image, thermal printhead assembly 1114 may provide a magenta color separation image, and thermal printhead assembly 1116 may provide a cyan color separation image to form a three color multicolor image on the receiver sheet. Fourth ribbon cassette assembly 1118 thermally transfers the transparent overcoat to protect the color image from for example fingerprints. At each of the four assemblies there is provided a thermal printhead 1119a-d that has recording elements selectively enabled in accordance with image information to selectively transfer color dye to the receiver or in the case of the transparent ribbon to transfer the overcoat layer to the now imaged receiver sheet. At each thermal print assembly, platen rollers 1113a-d, form a respective printing nip with the respective printhead 1119a-d. As the receiver is driven through each of the respective nips, the movement of the receiver advances corresponding primary color ribbon 1112c, 1114c, 1116c and 1118c through the respective nip as well. After each multicolor image is formed, a cutter 1115 maybe enabled to cut the receiver into a discrete sheet containing the multicolor image protected by the transparent overcoat layer.
In addition, the following test procedure for measuring voltages on image side of a printed sheet of receiver material is included below:
A Kodak Ektatherm™ donor and receiver from media kit type 838-0370 was used in this test. Black imaged samples of receiver material are generated by an experimental printer which transfers yellow, magenta, and cyan dye patches and a protective laminate patch onto the surface of the receiver. Samples were produced with and without grounding of the printer peel member 1205, and were measured for surface voltage using the procedure described below.
Probes from two Trek™ Model 347 Electrostatic Voltmeters are placed over an isolated metal plate (see
Readings from the two Trek™ Model 347 Electrostatic Voltmeters when the sheets of receiver material are mounted to the isolated metal surface plate:
The invention has been described in detail with particular reference to certain preferred embodiments thereof, but it will be understood that variations and modifications can be effected within the spirit and scope of the invention.
