Color printer with sensors arranged along a length of a ribbon for detecting the ribbon's position

Information

  • Patent Grant
  • 6493017
  • Patent Number
    6,493,017
  • Date Filed
    Wednesday, March 6, 2002
    22 years ago
  • Date Issued
    Tuesday, December 10, 2002
    22 years ago
Abstract
A color printer includes an ink ribbon having a plurality of sequentially arranged dye regions, each of the dye regions having a plurality of dye frames for carrying dye of different colors, a ribbon driving device for causing the ink ribbon to move in a predetermined direction, a controller for controlling the color printer, and a plurality of optical detecting devices sequentially arranged and mounted adjacent to the ink ribbon. At least two output signals are detected when each of the optical detecting devices senses a dye frame, and each the output signal is defined as a phase. Position of the ink ribbon is discerned by the controller according to the phase and phase-to-phase variation recorded by the optical detecting devices when the controller commands the ribbon driving device to move the ink ribbon.
Description




BACKGROUND OF INVENTION




1. Field of the Invention




The present invention relates to a photo printer, and more particularly, to a photo printer with sensors arranged along a length of a ribbon for detecting the ribbons position.




2. Description of the Prior Art




Please refer to FIG.


1


and FIG.


2


.

FIG. 1

is a perspective view of a conventional ink ribbon positioning system


10


.

FIG. 2

is a block diagram of a conventional color printer


50


. FIG.


1


and

FIG. 2

show the Taiwan Patent No. 399016 “INK RIBBON POSITIONING SYSTEM OF A COLOR PRINTER”. The ink ribbon positioning system


10


is used for identifying the position of a color ink ribbon


12


of the color printer


50


. The ink ribbon


12


is installed inside a ribbon cartridge (not shown) in a windable manner, and comprises a plurality of sequentially arranged dye regions


14


. Each of the dye regions


14


comprises four dye frames


16


,


18


,


20


,


22


for separatelycarrying yellow, magenta, cyan, and over coating dye. The ink ribbon


12


also comprises opaque regions


24


installed at the front and rear ends of the dye regions


14


.




The ink ribbon positioning system


10


comprises a light source


32


installed at one side of the ink ribbon


12


for emitting a light beam


34


of a predetermined color toward the ink ribbon


12


and an optical sensor


36


installed at the opposite side of the ink ribbon


12


fordetecting the light beam


34


passed through the ink ribbon


12


and generating a corresponding output voltage. The ink ribbon positioning system


10


also comprises an identification device


38


for identifying positions of the dye region


14


of the ink ribbon


12


and the dye frames


16


,


18


,


20


,


22


inside the dye region


14


according to the output voltages generated by the optical sensor


36


and generating corresponding position signals. The light beam


34


emitted by the light source


32


has different penetration rates for each of the four dye frames


16


,


18


,


20


,


22


inside the dye region


14


and for the opaque region


24


. Therefore, when two adjacent dye frames pass by the optical sensor


36


sequentially, the optical sensor


36


will generate different output voltages.




The color printer


50


comprises a winding mechanism


52


for winding the ink ribbon


12


inside the ribbon cartridge so that each of the dye frames


16


,


18


,


20


,


22


inside the dye region


14


pass by a thermal print head


54


sequentially, the thermal print head


54


for transferring the different colors of dye on the dye frames


16


,


18


,


20


,


22


onto a photo paper (not shown) sequentially, and a control circuit


40


for controlling operations of the winding mechanism


52


and the thermal print head


54


according to the position signals generated by the identification device


38


so as to form a desired pattern.




Because the light beam


34


emitted by the light source


32


has different penetration rates for each of the dye frames


16


,


18


,


20


,


22


and the opaque region


24


, as two adjacent dye frames pass by the optical sensor


36


in sequence, the optical sensor


36


will generate different output voltages. The identification device


38


will identify the positions of the dye region


14


and the dye frames


16


,


18


,


20


,


22


inside the dye region


14


according to the corresponding output voltages generated by the optical sensor


36


, and will generate corresponding position signals. The control circuit


40


will control the winding mechanism


52


to wind the ink ribbon


12


according to the position signals generated by the identification device


38


so as to pass the ink ribbon


12


by the thermal print head


54


for sequentially transferring dyes onto the photo paper.




The identification device


38


differentiates the positions of each of the four frames


16


,


18


,


20


,


22


inside the dye region


14


according to the light beam having different penetration rates for each frame. The identification device


38


comprises three comparators


42


,


44


,


46


with reference voltages between the four dye frames


16


,


18


,


20


,


22


and the opaque region


24


so as to discern the four distinct output voltages and generate corresponding position signals for identifying the positions of the dye frames


16


,


18


,


20


,


22


inside the dye region


14


of the ink ribbon


12


. However, the yellow dye frame


16


and the over coating dye frame


22


will generate the same output voltage, so the identification device


38


has to discern orders of the other dye frames (the magenta dye frame


18


and the cyan dye frame


20


) first to differentiate the yellow dye frame


16


from the over coating dye frame


22


. In addition, a particular barcode is printed at a front end of the yellow dye frame


16


and the over coating dye frame


22


respectively to distinguish the two. This causes the color printer


50


to need more time to identify the initial position of the ink ribbon


12


(the initial position of the yellow dye frame


16


) when the color printer


50


prints at the initial position of the yellow dye frame


16


. It also increases the amount of parts used, resulting in higher production costs.




SUMMARY OF INVENTION




It is therefore a primary objective of the present invention to provide a color printer with sensors arranged along a length of a ribbon for detecting the ribbons position to solve the above-mentioned problems.




In the claimed invention, the color printer comprises an ink ribbon capable of moving in a predetermined direction. The ink ribbon has a plurality of dye regions sequentially arranged in the predetermined direction on the ink ribbon. Each dye region includes a plurality of dye frames for carrying dye of different colors,a print head for transferring the dye of different colors stored in the dye frames onto an object to form a desired pattern,a ribbon driving device for causing the ribbon to move in the predetermined direction, a controller for controlling the color printer, and a plurality of optical detecting devices mounted adjacent to the ink ribbon and arranged sequentially along the predetermined direction. When each of the optical detecting devices senses a dye frame, at least two output signals are detected. Each output signal is defined as a phase. A position of the ink ribbon is discerned by the controller according to the phase and phase-to-phase variation recorded by the optical detecting devices when the controller commands the ribbon driving device to move the ink ribbon.




The ink ribbon positioning system in the present invention can search for an initial position of the dye frame of the ink ribbon according to the different phase-to-phase variations generated by the light sources and the photo sensors of the optical detecting devices without any identification devices, parts for measuring voltage variations, or particular barcodes to identify the ink ribbon, resulting in decreasing costs.




These and other objectives of the present invention will no doubt become obvious to those of ordinary skill in the art after reading the following detailed description of the preferred embodiment that is illustrated in the multiple figures and drawings.











BRIEF DESCRIPTION OF DRAWINGS





FIG. 1

is a perspective view of a conventional ink ribbon positioning system.





FIG. 2

is a block diagram of a conventional color printer.





FIG. 3

is a perspective view of an ink ribbon positioning system of a color printer according to the present invention.





FIG. 4

is a block diagram of the color printer according to the present invention.





FIG. 5

is a table contrasting phases with each corresponding dye frame and dividing section when the optical detecting devices utilize green light sources.





FIG. 6

is a table contrasting phases with each corresponding dye frame and dividing section when the optical detecting devices utilize red light sources.





FIG. 7

is a table contrasting phases and conversion codes generated by the photo sensor.





FIG. 8

is a perspective view of the ink ribbon positioning system of the color printer according to a first embodiment of the present invention.





FIG. 9A

is a time sequence diagram of phases generated by a photo sensor shown in FIG.


8


.





FIG. 9B

is a table contrasting the phase and conversion codes generated by the photo sensor shown in FIG.


9


A.





FIG. 10

is a perspective view of an ink ribbon positioning system of a color printer according to a second embodiment of the present invention.





FIG. 11A

is a time sequence diagram of phases generated by a photo sensor shown in FIG.


10


.





FIG. 11B

is a table contrasting the phase and conversion codes generated by the photo sensor shown in FIG.


11


A.











DETAILED DESCRIPTION




Please refer to FIG.


3


and FIG.


4


.

FIG. 3

is a perspective view of an ink ribbon positioning system


60


of a color printer


100


according to the present invention.

FIG. 4

is a block diagram of the color printer


100


according to the present invention. The color printer


100


is a photo printer including the ink ribbon positioning system


60


, an ink ribbon


62


capable of moving in a predetermined direction, a controller


90


, a thermal print head


102


, and a ribbon driving device


78


. The ink ribbon positioning system


60


is used for identifying the position of the ink ribbon


62


of the color printer


100


.The ink ribbon


62


is installed in a ribbon cartridge (not shown) and comprises a plurality of dye regions


64


sequentially arranged in the predetermined direction on the ink ribbon


62


. Each of the dye regions


64


includes four dye frames


66


,


68


,


70


,


72


for carrying dye ofyellow, magenta, cyan and over coating colors, respectively.




Adjacent to the yellow dye frame


66


, the magenta dye frame


68


, the cyan dye frame


70


, and the over coating dye frame


72


are disposed, respectively,an opaque dividing section


76


, a transparent dividing section


74


, a transparent dividing section


74


, and a transparent dividing section


74


that allows the controller


90


to discern an initial position of each of the four dye frames


66


,


68


,


70


,


72


. The controller


90


controls the color printer


100


. The ribbon driving device


78


causes the ink ribbon


62


stored in the ribbon cartridge to roll in the predetermined direction. The thermal print head


102


transfers the dye of different colors stored in the dye frames


66


,


68


,


70


,


72


onto a photo paper to form a desired pattern.




As shown in

FIG. 3

, the ink ribbon positioning system


60


comprises two optical detecting devices mounted adjacent to the ink ribbon


62


and arranged sequentially along the predetermined direction. The two optical detecting devices include a first light source


82


and a second light source


92


disposed at one side of the ink ribbon


62


for emitting a light beam of a predetermined color, and a first photo sensor


86


and a second photo sensor


96


disposed at the opposite side of the ink ribbon


62


for detecting transmitted light


84


and


94


which is emitted from the first light source


82


and the second light source


92


and penetrates the ink ribbon


62


, thereby generating corresponding output signals. When the controller


90


causes the ribbon driving device


78


to roll the ink ribbon


62


stored in the ribbon cartridge so as each of the dye frames


66


,


68


,


70


,


72


inside the dye region


64


pass by the thermal print head


102


sequentially, the first photo sensors


86


and the second photo sensor


96


sense the dye region


64


of the ink ribbon


62


thereby generating at least two different output signals. Each output signal is defined as a phase. Thereafter, when the controller


90


causes the ribbon driving device


78


to roll the ink ribbon


62


and then commands the thermal print head


102


to print the desired pattern, the position of the ink ribbon


62


is discerned by the controller


90


according to the phase and phase-to-phase variation recorded by the optical detecting devices.




The light beams


84


and


94


emitted by the first light source


82


and the second light source


92


have different penetration rates for each of the dye frames


66


,


68


,


70


,


72


, the opaque dividing section


76


, and the transparent dividing section


74


. As two adjacent dye frames pass by the first photo sensor


86


and the second photo sensor


96


sequentially, the first photo sensor


86


and the second photo sensor


96


generate different phases and phase-to-phase variations. After that, the position of the dye region


64


and the dye frames


66


,


68


,


70


,


72


inside the dye region


64


are discerned according to the phases and the phase-to-phase variations, causing the first photo sensor


86


and the second photo sensor


96


to generate corresponding position signals. The controller


90


causes the ribbon driving device


78


to wind the ink ribbon


62


passing by the thermal print head


102


, and then the thermal print head


102


transfers the dye of different colorsstored in the dye frames


66


,


68


,


70


,


72


onto the photo paper sequentially.




As mentioned above, the present invention discerns the position of the dye region


64


, and the dye frames


66


,


68


,


70


,


72


inside the dye region


64


according to the phases and the phase-to phase variations between each of the dye regions


64


to identify the initial position of the ink ribbon


62


.




Please refer to

FIG. 5

,

FIG. 6

, and FIG.


7


.

FIG. 5

is a table contrasting phases with each corresponding dye frame and dividing section when the optical detecting devices utilize green light sources.

FIG. 6

is a table contrasting phases with each corresponding dye frame and dividing section when the optical detecting devices utilize red light sources.

FIG. 7

is a table contrasting the phase and conversion codes generated by the photo sensor. As shown in FIG.


5


and

FIG. 6

, in the color printer


100


of the present invention, the light beam


84


(green) and the light beam


94


(red) emitted by the first light source


82


and the second light source


92


of the optical detecting device have different penetration rates for each of the dye regions


64


of the ink ribbon


62


, each of the dye frames


66


,


68


,


70


,


72


, the opaque dividing section


76


, and the transparent dividing section


74


. As a result, the first photo sensor


86


and the second photo sensor


96


generate only two different output signals, namely a high phase and a low phase (represented by “1” and “0” respectively). As shown in

FIG. 7

, the phases of the dye frames


66


,


68


,


70


,


72


and the dividing sections


74


and


76


generated by the two photo sensors


86


and


96


are converted to corresponding conversion codes. When two predetermined conversion codes are represented continuously, the initial position of the ink ribbon


62


is discerned (from the initial position of the yellow dye frame


66


). The details are described as follows.




Please refer to

FIG. 8

,

FIG. 9A

, and FIG.


9


B.

FIG. 8

is a perspective view of the ink ribbon positioning system


60


of the color printer


100


according to a first embodiment of the present invention.

FIG. 9A

is a time sequence diagram of the phase generated by the photo sensor shown in FIG.


8


.

FIG. 9B

is a table contrasting the phase and the conversion code generated by the photo sensor shown in FIG.


9


A. The ink ribbon


62


comprises theplurality of dye regions


64


sequentially arranged in the predetermined direction. Each of the dye regions


64


consists of the four dye frames


66


,


68


,


70


,


72


for carrying dye of yellow, magenta, cyan, and over coating colors. Each of the dye frames


66


,


68


,


70


,


72


has a substantially equal first length


112


. The opaque dividing section


76


and the three transparent dividing sections


74


are positioned at the front end of each of the dye frames


66


,


68


,


70


,


72


, and allow the controller


90


to discern an initial position of each of the four dye frames


66


,


68


,


70


,


72


. Each dividing section has a substantially equal second length


114


. The controller


90


controls the color printer


100


, and the ribbon driving device


78


causes the ink ribbon


62


stored in the ribbon cartridge to roll in the predetermined direction. The thermal print head


102


transfers the dye of different colors stored in the dye frames


66


,


68


,


70


,


72


onto a photo paper to form a desired pattern.




As shown in

FIG. 8

, the ink ribbon positioning system


60


comprises two optical detecting devices mounted adjacent to the ink ribbon


62


and arranged sequentially along the predetermined direction, with a distance of a third length


16


between the two optical detecting devices. The first length


112


is greater than the second length


114


, and the third length


116


is greater than the second length


114


.




As shown in

FIG. 9A

, when the controller


90


causes the ribbon driving device


78


to wind the ink ribbon


62


stored in the ink ribbon cartridge, causing the dye frames


66


,


68


,


70


,


72


inside the dye region


64


to pass by the thermal print head


102


sequentially, the first photo sensor


86


and the second photo sensor


96


sense the dye region


64


of the ink ribbon


62


, thereby generating two different phases. Therefore, twelve state-to state variations S


1


, S


2


, S


3


, S


4


, S


5


, S


6


, S


7


, S


8


, S


9


, S


10


, S


11


, S


12


are generated along a time axis when the first photo sensor


86


and the second photo sensor


96


sense a dye frame of the dye region


64


. The printing order of the ink ribbon


62


is the yellow dye frame


66


, the magenta dye frame


68


, the cyan dye frame


70


, and the over coating dye frame


72


. This means that the controller


90


will search for the yellow dye frame


66


first, then search for the magenta dye frame


68


, the cyan dye frame


70


, and the over coating frame


72


in sequence to identify the initial position of the ink ribbon


62


. The details are described as follows (please refer to

FIG. 5

,

FIG. 8

, FIG.


9


A and FIG.


9


B): Step


130


:Search for the yellow dye frame


66


. Turn on the two green light sources


82


,


92


and the two photo sensors


86


,


96


, and wind the ink ribbon


62


; Step


132


:Search for the phase “11”, it could be S


1


, S


3


or S


5


, and then wind the ink ribbon


62


continuously;Step


134


:Search for the next state. If the phase is “01”, it could be S


2


or


56


, and then perform step


136


and wind the ink ribbon


62


continuously. If the phase is “10”, it is S


4


, go back and perform step


132


.




Step


136


:Search for next state. If the phase is “11”, it is S


3


. Namely, the initial position of the yellow dye frame


66


is detected, and the color printer


100


can start to transfer the dye on the yellow dye frame


66


onto the photo paper. Thereafter perform step


138


and search for the magenta dye frame


68


. If the phase is “00”, it is S


7


, go back and perform step


132


.




Step


138


:Search for the magenta dye frame


68


. Because printing of the dye on the yellow dye frame


66


onto the photo paper has just finished, the photo sensor


86


must still be within the yellow dye frame


66


. Continuously wind the ink ribbon


62


. When the phase generated by the photo sensor


86


goes from “1” to “0”, the initial position of the magenta dye frame


68


is detected. Then, start to transfer the dye on the magenta dye frame


68


onto the photo paper. Thereafter perform step


140


to search for the cyan dye frame


70


.




Step


140


:Search for the cyan dye frame


70


. Because printing of the dye on the magenta dye frame


68


onto the photo paper has just finished, the photo sensor


86


must still be within the magenta dye frame


64


. Continuously wind the ink ribbon


62


. When the phase generated by the photo sensor


86


goes from “0” to “1”, the initial position of the transparent dividing section


74


is detected. When the phase generated by the photo sensor


86


goes from “1” to “0” again, the initial position of the cyan dye frame


70


is detected. Then, start to print the dye on the cyan dye frame


70


onto the photo paper. Thereafter perform step


142


to search for the over coating dye frame


72


.




Step


142


:Search for the over coating dye frame


72


. Because printing of the dye on the cyan dye frame


70


onto the photo paper has just finished, the photo sensor


86


must still be within the cyan dye frame


70


. Continuously wind the ink ribbon


62


. When the phase generated by the photo sensor


86


goes from “0” to “1”, the initial position of the over coating dye frame


72


is detected. Then, start to print the dye on the over coating dye frame


72


onto the photo paper.




According to the above-mentioned steps, the ink ribbon positioning system


60


of the color printer


100


in the first embodiment of the present invention utilizes the two green light sources


82


,


92


together with the photo sensors


86


,


96


to sense the initial position of the ink ribbon


62


. Then the phase and the conversion code of each part of the ink ribbon


62


are determined using a digital conversion manner. The initial position of the yellow dye frame


66


is discerned by utilizing the variation of the conversion codes (as mentioned above, finding where the conversion code changes from “1” to “3”). The yellow dye frame


66


serves as the initial position of the ink ribbon


62


for printing the dye onto the photo paper. Thereafter, the initial position of the magenta dye frame


68


, the cyan dye frame


70


, and the over coating dye frame


70


can be determined by utilizing the phase variations. In this manner, the color printer


100


according to the present invention can detect the position of the ink ribbon


62


.




Please refer to

FIG. 10

,

FIG. 11A

, and FIG.


11


B.

FIG. 10

is a perspective view of the ink ribbon positioning system


60


of the color printer


100


according to a second embodiment of the present invention.

FIG. 11A

is a time sequence diagram of the phase generated by the photo sensor shown in FIG.


10


.

FIG. 11B

is a table contrasting the phase and the conversion code generated by the photo sensor shown in FIG.


11


A. The ink ribbon


62


comprises theplurality of dye regions


64


sequentially arranged in the predetermined direction. Each of the dye regions


64


consists of four dye frames


66


,


68


,


70


,


72


for carrying dye of yellow, magenta, cyan and over coating colors, and each of the dye frames


66


,


68


,


70


,


72


has a substantially equal first length


112


. The opaque dividing section


76


and the three transparent dividing sections


74


are positioned at the front end of each of the dye frames


66


,


68


,


70


,


72


, that allows the controller


90


to discern the initial position of each of the four dye frames


66


,


68


,


70


,


72


, and each dividing section has the substantially equal second length


114


. The controller


90


controls the color printer


100


, and the ribbon driving device


78


causes the ink ribbon


62


stored in the ribbon cartridge to roll in the predetermined direction. The thermal print head


102


transfers the dye of different colors stored in the dye frames


66


,


68


,


70


,


72


onto the photo paper to form a desired pattern.




As shown in

FIG. 10

, the ink ribbon positioning system


60


comprises two optical detecting devices mounted adjacent to the ink ribbon


62


and arranged sequentially along the predetermined direction, and a distance between the two optical detecting devices is a third length


118


. Unlike the first embodiment, the first length


112


is greater than the second length


114


, and the third length


118


is less than the second length


114


. Each of the optical detecting devices includes the first light source


82


and the second light source


92


installed at one side of the ink ribbon


62


for respectively emitting the light beam


84


of red color and the light beam of green color, and the first photo sensor


86


and the second photo sensor


96


installed at the opposite side of the ink ribbon


62


for detecting transmitted lights


84


and


94


emitted by the first light source


84


and the second light source


94


. The transmitted lights


84


and


94


penetrate the ink ribbon


62


, thereby generating corresponding position signals. At least one dye frame


66


,


68


,


70


,


72


inside each of the dye regions


64


causes the first photo sensor


86


and the second photo sensor


96


to generate different output signals (i.e. phase).




As shown in

FIG. 11A

, when the controller


90


causes the ribbon driving device


78


to wind the ink ribbon


62


stored in the ink ribbon cartridge so as to cause the dye frames


66


,


68


,


70


,


72


inside the dye region


64


to pass by the thermal print head


102


sequentially, the first photo sensor


86


and the second photo sensor


96


sense the dye region


64


of the ink ribbon


62


, thereby generating two different phases. Therefore, eight state-to state variations S


1


, S


2


, S


3


, S


4


, S


5


, S


6


, S


7


, S


8


are generated along a time axis when the first photo sensor


86


and the second photo sensor


96


sense dye frames of the dye region


64


. The details are described as follows (please refer to

FIG. 5

,

FIG. 6

,

FIG. 10

, FIG.


11


A and FIG.


11


B):Step


150


:Search for the yellow dye frame


66


. Turn on the red light source


82


, thegreen light sources


92


and the two photo sensors


86


,


96


, and wind the ink ribbon


62


; Step


152


:Search for the phase “11”, it could be S


1


or S


5


, and then wind the ink ribbon


62


continuously; Step


154


:Search for the next state. If the phase is “01”, it is S


2


, namely the initial position of the yellow dye frame


66


is detected (due to a distance between the thermal print head


102


and the first photo sensor


86


). When the conversion code goes from “3” to “01”, the color printer


100


can start to transfer the dye on the yellow dye frame


66


onto the photo paper, and then perform step


156


and search for the magenta dye frame


68


. If the phase is “10”, it is S


6


, and then step


152


is performed.




Step


156


:Search for the magenta dye frame


68


. Because printing of the dye on the yellow dye frame


66


onto the photo paper has just finished, the second photo sensor


96


must still be within the yellow dye frame


66


. Continuously wind the ink ribbon


62


. When the phase generated by the second photo sensor


96


goes from “1” to “0”, the initial position of the magenta dye frame


68


is detected. Then, start to transfer the dye on the magenta dye frame


68


onto the photo paper. Thereafter perform step


158


to search for the cyan dye frame


70


.




Step


158


:Search for the cyan dye frame


70


. Because printing of the dye on the magenta dye frame


68


onto the photo paper has just finished, the first photo sensor


86


must still be within the magenta dye frame


64


. Continuously wind the ink ribbon


62


. When the phase generated by the first photo sensor


86


goes from “1” to “0”, the initial position of the transparent dividing section


74


is detected. When the phase generated by the first photo sensor


86


goes from “1” to “0” again, the initial position of the cyan dye frame


70


is detected. Then, start to print the dye on the cyan dye frame


70


onto the photo paper. Thereafter perform step


160


to search for the over coating dye frame


72


.




Step


160


:Search for the over coating dye frame


72


. Because printing of the dye on the cyan dye frame


70


onto the photo paper has just finished, the first photo sensor


86


must still be within the cyan dye frame


70


. Continuously wind the ink ribbon


62


. When the phase generated by the first photo sensor


86


goes from “0” to “1”, the initial position of the over coating dye frame


72


is detected. Then, start to print the dye on the over coating dye frame


72


onto the photo paper.




According to the above-mentioned steps, the ink ribbon positioning system


60


of the color printer


100


in the second embodiment of the present invention utilizes the red light source


82


and the green light source


92


together with the photo sensors


86


,


96


to sense the initial position of the ink ribbon


62


. Like the first embodiment, the phase and the conversion code of each part of the ink ribbon


62


are determined by using a digital conversion manner. The initial position of the yellow dye frame


66


is discerned by utilizing the variation of the conversion codes (as mentioned above, finding the conversion code goes from “1” to “3”). The yellow dye frame


66


serves as the initial position of the ink ribbon


62


for printing the dye onto the photo paper. Thereafter, the initial position of the magenta dye frame


68


, the cyan dye frame


70


, and the over coating dye frame


70


can be discerned by utilizing the phase variations. In this manner, the color printer


100


according to the present invention can detect the position of the ink ribbon


62


.




The four dye frames are used as an example in the embodiments of the present. invention. Actually, three dye frames without the over coating dye frame can be used in the present invention to explain the ink ribbon positioning system. In addition, the present invention utilizes the two light sources of green light beams with the two photo sensors, or uses light sources of red and green light beams with the two photo sensors, to generate the phases and the conversion codes of each part of the ink ribbon. However, in the present invention the first light source and the second light source can also be other colors such as (green, red), (cyan, red), (cyan, green) etc., or be the same color such as (cyan, cyan) etc. Any combination of colors can be used in order to generate different phases and states. Further, the initial position of the ink ribbon can be discerned according to the two predetermined phases generated by the first photo sensor and the second photo sensor or the two predetermined conversion codes. In addition, in the present invention, the photo sensors and the light sources are installed at opposite sides of the ink ribbon. In fact, the photo sensors and the light sources can be installed at the same side of the ink ribbon if a reflector is installed at the opposite side of the ink ribbon for reflecting the light beams back to the photo sensors for generating the phases.




Compared with the conventional ink ribbon positioning system of the color printer, the ink ribbon positioning system


60


of the present invention discerns the initial position of the dye frame of the ink ribbon according to the different phase-to-phase variations generated by the light sources and the photo sensors of the optical detecting devices without the need for any identification devices, parts for measuring voltage variations, or particular barcodes to identify the ink ribbon, resulting in decreased costs.




Those skilled in the art will readily observe that numerous modification and alterations of the device may be made while retaining the teachings of the invention. Accordingly, the above disclosure should be construed as a limited only by the metes and bounds of the appended claims.



Claims
  • 1. A color printer comprising:an ink ribbon capable of moving in a predetermined direction, comprising a plurality of dye regions sequentially arranged in said predetermined direction on said ink ribbon, and each of said dye regions comprising a plurality of dye frames for carrying dye of different colors; a print head for transferring said dye of different colors stored in said dye frames onto an object to form a desired pattern; a ribbon driving device for causing said ink ribbon to move in said predetermined direction; a plurality of optical detecting devices mounted adjacent to said ink ribbon and arranged sequentially along said predetermined direction, wherein at least two output signals are detected when each of said optical detecting devices senses a dye frame, and wherein each said output signal is defined as a phase; and a controller for controlling said color printer; wherein position of said ink ribbon is discerned by said controller according to said phase and phase-to-phase variation recorded by said optical detecting devices when said controller commands said ribbon driving device to move said ink ribbon.
  • 2. The color printer of claim 1, wherein said color printer comprises only two optical detecting devices and each of said optical detecting devices generates only two different output signals when said optical detecting device senses a dye frame of said dye region.
  • 3. The color printer of claim 1, wherein each of said optical detecting devices includes a light source and a photo sensor for detecting a transmitted light which is emitted from said light source and penetrates said ink ribbon thereby generating said output signals.
  • 4. The color printer of claim 2, wherein each of said dye regions includes four dye frames, and adjacent to each of said four dye frame is disposed a dividing section that allows said controller to discern an initial position of each of said four dye frames.
  • 5. The color printer of claim 4, wherein said four dye frames comprise a yellow dye frame, a magenta dye frame, a cyan dye frame, and an over coating dye frame.
  • 6. The color printer of claim 5, wherein adjacent to said yellow dye frame, magenta dye frame, cyan dye frame, and over coating dye frame are disposed, respectively, an opaque dividing section, a first transparent dividing section, a second transparent dividing section, and a third transparent dividing section.
  • 7. The color printer of claim 3, wherein at least two of said optical detecting devices have light sources emitting a light beam of a predetermined color.
  • 8. The color printer of claim 4, wherein each of said dye frames has a substantially equal first length, said dividing section has a second length and a distance between two said optical detecting devices is a third length where said first length is greater than said third length, and said third length is greater than said second length.
  • 9. The color printer of claim 3, wherein said plurality of optical sensing devices comprises at least two optical sensing devices having light sources emitting light beams of different colors, and at least one of said dye frames in each of said dye regions produces said output signals when being detected by said two optical sensing devices.
  • 10. The color printer of claim 4, wherein each of said dye frames has a substantially equal first length, said dividing section has a second length and a distance between two said optical detecting devices is a third length where said first length is greater than said second length, and said second length is greater than said third length.
  • 11. The color printer of claim 1 further comprising a ribbon cartridge for storing said ink ribbon, and said ribbon driving device causes said ink ribbon stored in said ribbon cartridge to roll in said predetermined direction.
  • 12. The color printer of claim 1, wherein said color printer is a photo printer.
Priority Claims (1)
Number Date Country Kind
90120144 A Aug 2001 TW
US Referenced Citations (6)
Number Name Date Kind
4710781 Stephenson Dec 1987 A
RE33260 Stephenson Jul 1990 E
5751601 Tang et al. May 1998 A
6071024 Chi-Ming et al. Jun 2000 A
6080993 Zwijsen Jun 2000 A
6396526 Sung et al. May 2002 B1
Foreign Referenced Citations (1)
Number Date Country
11-180016 Jul 1999 JP