Rotatable charging apparatus, and printing machine including the same

Information

  • Patent Grant
  • 6308032
  • Patent Number
    6,308,032
  • Date Filed
    Tuesday, September 19, 2000
    24 years ago
  • Date Issued
    Tuesday, October 23, 2001
    23 years ago
Abstract
A rotatable charging apparatus includes a length extending between a first end and a second end, with the rotatable charging apparatus centered about an axis parallel to the length. The rotatable charging apparatus outer periphery forms N apparatus positions. One charging device is fixed to each of N−1 apparatus positions. The remaining (Nth) apparatus position is devoid of a charging device, thus forming an “empty” charging device position. A host printing machine selectively causes the rotatable charging apparatus to rotate about its axis thereby selectively position any of its N−1 charging devices to face a proximately-located photosensitive element. When a problem exists with the current charging device, or when the total number of operating hours of the current charging device exceeds a fixed threshold, the printing machine causes the rotatable charging apparatus to rotate from its current charging device to position a new charging device facing the photosensitive element. Also, the printing machine causes the rotatable charging apparatus to rotate from its current charging device to the empty charging device position facing the photosensitive element when a power-down or hard-stop condition exists in the printing machine.
Description




FIELD OF THE INVENTION




This application relates to xerography including, but not limited to, rotatable charging apparatus.




BACKGROUND OF THE INVENTION




Current xerographic printing machines use charging devices in the charging, recharging, pre-transfer, transfer, de-tack and pre-clean stations. Charging devices comprise several types, including glass-coated alternating-current wire scorotrons, also known as discorotrons, and solid-state devices, also known as “microtrons”.




These two devices, discorotrons and solid-state chargers, each provide substantially different operating characteristics. For example, while the operating-life of a discorotron is substantial, the discorotron generates a substantial amount of undesirable gaseous emissions such as, for example, ozone. In contrast, while a solid-state charger has a relatively short life, the solid-state charger produces only a fraction of the ozone of the equivalent discorotron. For example, in a preliminary experiment, a solid-state charger emitted only about one-seventh ({fraction (1/7)}) of the ozone emitted by the equivalent discorotron.




What is needed, therefore, is an improved charging apparatus that generates acceptable amounts of undesirable ozone gas while still providing a satisfactory operating life.




SUMMARY OF THE INVENTION




In one aspect of the invention, a rotatable charging apparatus comprises an apparatus length extending between a first end and a second end and centered about an axis parallel to the apparatus length, with plural charging devices fixed to an apparatus periphery surrounding the axis, the rotatable charging apparatus rotatable about the axis to thereby selectively position any charging device to face a proximate photosensitive element.




In another aspect of the invention, a printing machine comprises rotatable charging apparatus, the rotatable charging apparatus comprising an apparatus length extending between a first end and a second end and centered about an axis parallel to the apparatus length, with plural charging devices fixed to an apparatus periphery surrounding the axis, the rotatable charging apparatus rotatable about the axis to thereby selectively position any charging device to face a proximate photosensitive element.











BRIEF DESCRIPTION OF THE DRAWINGS





FIG. 1

is an elevated perspective view of a first embodiment of a rotatable charging apparatus


10


, in accordance with the present invention.





FIG. 2

is a side view of the rotatable charging apparatus


10


positioned so that apparatus surface


18


which is devoid of a charging device, thus forming an “empty” charging device position


18


, faces a proximate photosensitive element


2000


.





FIG. 3

is a side view of the rotatable charging apparatus


10


positioned so that charging device


110


mounted on apparatus surface


11


faces the proximate photosensitive element


2000


.





FIG. 4

is an elevated perspective view of a second embodiment of a rotatable charging apparatus


1000


, in accordance with the present invention.





FIG. 5

is a side view of the rotatable charging apparatus


1000


positioned so that apparatus position


1018


which is devoid of a charging device, thus forming an “empty” charging device position


1018


, faces a proximate photosensitive element


2000


.





FIG. 6

is a side view of the rotatable charging apparatus


1000


positioned so that charging device


1110


mounted at apparatus position


1011


faces the proximate photosensitive element


2000


.





FIG. 7

is a block diagram of a printing machine


700


, which printing machine comprises a rotatable charging apparatus


7000


, in accordance with the present invention.





FIG. 8

is a first flow diagram for the printing machine


700


of FIG.


7


.





FIG. 9

is a second flow diagram for the printing machine


700


of FIG.


7


.











DESCRIPTION OF THE PREFERRED EMBODIMENTS




Briefly, a rotatable charging apparatus comprises a length extending between a first end and a second end, with the rotatable charging apparatus centered about an axis parallel to the length. The rotatable charging apparatus outer periphery forms N apparatus positions. One charging device is fixed to each of N−1 apparatus positions. The remaining (Nth) apparatus position is devoid of a charging device, thus forming an “empty” charging device position. A host printing machine selectively causes the rotatable charging apparatus to rotate about its axis to thereby selectively position any of its N−1 charging devices to face a proximately-located photosensitive element. When a problem exists with the current charging device, or when the total number of operating hours of the current charging device exceeds a fixed threshold, the printing machine causes the rotatable charging apparatus to rotate from its current charging device to position a new charging device facing the photosensitive element. The displaced charging device is de-energized and the new device facing the photosensitive element is energized. Also, the printing machine causes the rotatable charging apparatus to rotate from its current charging device to the empty charging device position facing the photosensitive element when a power-down or hard-stop condition exists in the printing machine.




Referring now to

FIG. 1

, there is shown a first embodiment of a rotatable charging apparatus


10


, in accordance with the present invention.




As shown in

FIG. 1

, the rotatable charging apparatus


10


comprises an apparatus length


31


extending between a first end


21


and a second end


22


and centered about an axis


1


parallel to the apparatus length


31


. As shown, the rotatable charging apparatus


10


comprises a plurality of charging devices generally designated by reference numerals


110


-


170


fixed to an apparatus periphery


90


surrounding the axis


1


.




Referring now to

FIG. 2

, as depicted therein, the rotatable charging apparatus


10


is arranged to rotate about the axis


1


to thereby selectively position any charging device of the plurality of charging devices


110


-


170


to face a proximate photosensitive element


2000


. In one embodiment, for example, the photosensitive element


2000


comprises a photoreceptor belt moving in a process direction


2001


, as depicted in FIG.


2


. Those skilled in the art will know that, in another embodiment, the photosensitive element


2000


may comprise a photoreceptor drum.




In one embodiment, each of the charging devices


110


-


170


comprises a solid-state charger, also known as a “microtron”.




In one embodiment, each of the charging devices


110


-


170


is similar to the solid-state charger disclosed in the aforementioned U.S. Pat. No. 5,563,688.




In another embodiment, each of the charging devices


110


-


170


is similar to the solid-state charger disclosed in the publication of Yasuo Hosaka and Hideyuki Nakoa, “Small-size and less-ozone-emitting solid-state charger for printers or copy machines,” IS&T's NIP 12: International Conference on Digital Printing Technologies, Oct. 27 through Nov. 1, 1996, San Antonio, Tex., pages 339 through 342, the disclosure of which publication is hereby incorporated by reference.




It will be appreciated that, in still further embodiments, each of the charging devices


110


-


170


comprises a still further type of charging device, which type of charging device generates only acceptable amounts of undesirable gaseous emissions including, without limitation, ozone.




Referring again to

FIG. 1

, as depicted therein, the apparatus periphery


90


comprises a plurality of apparatus surfaces


11


-


18


. It will be understood that each apparatus surface


11


-


18


forms a corresponding charging device position. As shown, each charging device of the plural charging devices


110


-


170


is fixed to an apparatus surface of the plural apparatus surfaces


11


-


18


.




Referring generally to

FIGS. 1-3

, in one embodiment, the first end


21


and the second end


22


of the rotatable charging apparatus


10


respectively form first and second polygons. Each of the first and second polygons


21


-


22


comprise a fixed number (“N”) of sides. In one embodiment, for example, and as particularly depicted in

FIGS. 1-3

, the rotatable charging apparatus


10


is arranged so that the value of N, the fixed number of end polygon sides, is 8.




Assuming, as depicted in

FIGS. 1-3

, that N equals 8, in one embodiment, the rotatable charging apparatus


10


has an apparatus width


32


of about 12 mm, with each of the plurality of charging devices


110


-


170


comprising a charging device width


112


-


172


of about 5 mm. Still assuming that N equals 8, in a further embodiment, the charging device


10


apparatus width


32


is about 16.8 mm, with each charging device of the plurality of charging devices


110


-


170


comprising a charging device width


112


-


172


of about 7 mm.




As depicted in

FIGS. 1-3

, each of the charging devices


110


-


170


further comprises a charging device thickness of about 1-5 mm and a charging device length about equal to the surface width of the photosensitive element


2000


. (The photosensitive element


2000


is depicted in

FIGS. 2-3

.)




In contrast to the aforementioned embodiment of

FIGS. 1-3

, however, it will be appreciated that, in still further embodiments, N has a value different than 8. In these latter embodiments, for example, N has a value below 8 (such as 7, 6, 5, etc.) or above 8 (such as 9, 10, 11, 12, etc.).




As depicted in

FIGS. 2-3

, in one embodiment, the rotatable charging apparatus


10


is arranged so that at least one apparatus surface of the plurality of apparatus surfaces


11


-


18


is devoid of a charging device, thus forming an “empty” charging device position. In one embodiment, for example, and as depicted in

FIGS. 2-3

, a single apparatus surface


18


is devoid of a charging device, thus forming an empty charging device position


18


.




In contrast to the aforementioned embodiment of

FIGS. 2-3

, however, it will be appreciated that, in further embodiments, any apparatus surface of the plurality of apparatus surfaces


11


-


18


may be devoid of a charging device. In these latter embodiments, for example, the apparatus surface


11


,


12


or


13


, etc., is devoid of a charging device.




In further contrast to the aforementioned embodiment of

FIGS. 2-3

, however, it will be appreciated that, in still further embodiments, more than one apparatus surfaces of the plurality of apparatus surfaces


11


-


18


are devoid of a charging device. In these latter embodiments, for example, two, three, four, or any greater number of the plural apparatus surfaces


11


-


17


are devoid of a charging device.




Also, it will be understood that a set of apparatus surfaces devoid of charging devices may comprise member apparatus surfaces of any of the plural apparatus surfaces


11


-


18


. Thus, for example, a set of two (2) apparatus surfaces devoid of charging devices may comprise member apparatus surfaces


11


and


12


;


11


and


13


;


11


and


14


;


11


and


15


;


11


and


16


;


11


and


17


; or other combination of surfaces.




Referring now to

FIG. 4

, there is shown a second embodiment of a rotatable charging apparatus


1000


, in accordance with the present invention.




As shown in

FIG. 4

, the rotatable charging apparatus


1000


comprises an apparatus length


1031


extending between a first end


1021


and a second end


1022


and centered about an axis


1001


parallel to the apparatus length


1031


. As shown, the rotatable charging apparatus


1000


comprises a plurality of charging devices generally designated by reference numerals


1110


-


1170


fixed to an apparatus periphery


1090


surrounding the axis


1001


.




As shown in

FIG. 5

, the rotatable charging apparatus


1000


is arranged to rotate about the axis


1001


to thereby selectively position any charging device of the plurality of charging devices


1110


-


1170


to face a proximate photosensitive element


2000


. In one embodiment, for example, the photosensitive element


2000


comprises a photoreceptor belt moving in a process direction


2001


, as depicted in FIG.


5


. Those skilled in the art will know that, in another embodiment, the photosensitive element


2000


may comprise a photoreceptor drum.




In one embodiment, each of the charging devices


1110


-


1170


comprises a solid-state charger, or microtron.




In one embodiment, each of the charging devices


1110


-


1170


is similar to the solid-state charger of the above U.S. Pat. No. 5,563,688.




In another embodiment, each of the charging devices


1110


-


1170


is based on the above publication of Yasuo Hosaka and Hideyuki Nakoa.




It will be appreciated that, in still further embodiments, each of the charging devices


1110


-


1170


comprises a still further type of charging device, which type of charging device generates only acceptable amounts of undesirable gaseous emissions including, without limitation, ozone.




Referring again to

FIG. 4

, as depicted therein, the apparatus periphery


1090


comprises a plurality of apparatus positions


1011


-


1018


. As shown, each charging device of the plural charging devices


1110


-


1170


is fixed to an apparatus position of the plural apparatus positions


1011


-


1018


.




Referring to

FIGS. 4-6

, in one embodiment, the first end


1021


and the second end


1022


of the rotatable charging apparatus


1000


generally are circular-shaped. The apparatus periphery


1090


comprises a fixed number (“N”) of apparatus positions. In one embodiment, for example, and as particularly depicted in

FIGS. 4-6

, the rotatable charging apparatus


1000


is arranged so that the value of N, the fixed number of apparatus positions, is 8.




Assuming, as depicted in

FIGS. 4-6

, that N equals 8, in one embodiment, the rotatable charging apparatus


1000


has an apparatus width


1032


of about 12 mm, with each of the plurality of charging devices


1110


-


1170


comprising a charging device width


1112


-


1172


of about 5 mm. Still assuming that N equals 8, in a further embodiment, the charging device


1010


apparatus width


1032


is about 16.8 mm, with each charging device of the plurality of charging devices


1110


-


1170


comprising a charging device width


1112


-


1172


of about 7 mm.




As depicted in

FIG. 4

, each of the charging devices


1110


-


1170


further comprises a charging device thickness of about 1-5 mm and a charging device length about equal to the surface width of the photosensitive element


2000


.




In contrast to the aforementioned embodiment of

FIGS. 4-6

, however, it will be appreciated that, in still further embodiments, N is a value different than 8. In these latter embodiments, for example, N has a value below 8 (such as 7, 6, 5, etc.) or above 8 (such as 9, 10, 11, 12, etc.).




As depicted in

FIGS. 5-6

, in one embodiment, the rotatable charging apparatus


1000


is arranged so that at least one apparatus position of the plurality of apparatus positions


1011


-


1018


is devoid of a charging device, thus forming an “empty” charging device position. In one embodiment, for example, and as depicted in

FIGS. 5-6

, a single apparatus position


1018


is devoid of a charging device, thus forming an empty charging position


1018


.




In contrast to this aforementioned embodiment of

FIGS. 5-6

, however, it will be appreciated that, in still further embodiments, any apparatus position of the plurality of apparatus positions


1011


-


1018


may be devoid of a charging device. In these latter embodiments, for example, the apparatus position


1011


,


1012


or


1013


, etc., is devoid of a charging device.




In further contrast to the aforementioned embodiment of

FIGS. 5-6

, however, it will be appreciated that, in still further embodiments, more than one apparatus positions of the plurality of apparatus positions


1011


-


1018


are devoid of a charging device. In these latter embodiments, for example, two, three, four, or any greater number of apparatus positions of the plurality of apparatus positions


1011


-


1018


are devoid of a charging device.




Also, it will be understood that a set of apparatus positions devoid of charging devices may comprise member apparatus positions of any of the plural apparatus positions


1011


-


1018


. Thus, for example, a set of two (2) apparatus positions devoid of charging devices may comprise member apparatus positions


1011


and


1012


;


1011


and


1013


;


1011


and


1014


;


1011


and


1015


;


1011


and


1016


;


1011


and


1017


; or other combination of positions.




Referring now to

FIG. 7

there is depicted a printing machine


700


including a rotatable charging apparatus


7000


, in accordance with the present invention. In one embodiment, the rotatable charging apparatus


7000


comprises the rotatable charging apparatus


10


disclosed by

FIGS. 1-3

and the foregoing written description corresponding thereto. In another embodiment, the rotatable charging apparatus


7000


comprises the rotatable charging apparatus


1000


disclosed by

FIGS. 4-6

and the foregoing written description corresponding thereto.




As discussed hereinabove, one key feature of the

FIG. 7

present rotatable charging apparatus


7000


(corresponding to the foregoing element


10


or element


1010


) is its ability to rotate about its axis (corresponding to the foregoing element


1


or element


1001


) to thereby selectively position any single charging device of its plural charging devices (corresponding to the foregoing elements


110


-


170


or elements


1110


-


1170


) to face the proximately-located photosensitive element


2000


that is moving in a process direction


2001


.




As shown in

FIG. 7

, the printing machine


700


includes a controller


3000


coupled to the rotatable charging apparatus


7000


by means of a control path


3001


. The controller


3000


is arranged to selectively control the rotation of the rotatable charging apparatus


7000


and thereby, in turn, selectively position any charging device to the photoreceptor


2000


. In

FIG. 7

, the selective positioning of a “current” charging device to the photoreceptor


2000


is depicted by the numeral


7001


.




In one embodiment, the controller


3000


comprises a suitably-programmed processor or the like.




In one embodiment, the controller


3000


is arranged to control the rotatable charging apparatus


7000


in accordance with a first process


800


depicted in FIG.


8


.




Referring now to

FIG. 8

, as depicted therein, the process starts at step


801


, and then proceeds to step


803


.




In step


803


, the process determines when the “age” of the charging device that is currently facing the photoreceptor


2000


, known as the “current charging device”, exceeds a fixed threshold. In one embodiment, the current charging device age is determined based on the total number of hours of operation of the current charging device. When step


803


determines that the age of the current charging device exceeds the fixed threshold, the process goes to step


807


. Otherwise, after step


803


, the process goes to step


805


.




In step


805


, the process determines when a problem exists with the current charging device. In one embodiment, a “problem” is defined as premature charging device failure, or massive dirt contamination, or non-uniform charging conditions. When step


805


determines that a problem exists with the current charging device, the process goes to step


807


. Otherwise, after step


805


, the process goes to step


809


.




In step


807


, the process rotates the rotatable charging apparatus


7000


from its current charging device to a new charging device facing the photosensitive element


2000


. After step


807


, the process goes to step


809


.




At step


809


, the process ends.




Returning again to

FIG. 7

, it will be understood that the rotatable charging apparatus


7000


(corresponding to either element


10


or


1010


) includes at least one empty charging device position. This is summarized as follows. In the rotatable charging apparatus


10


of

FIGS. 1-3

, at least one apparatus surface (or position) of the plural apparatus surfaces


11


-


17


is devoid of a charging device, thus corresponding to at least one empty charging device position therein. Likewise, in the rotatable charging apparatus


1010


of

FIGS. 4-6

, at least one apparatus position of the plural apparatus positions


1011


-


1017


is devoid of a charging device, thus corresponding to at least one empty charging device position therein.




As a result of the rotatable charging apparatus


10


or


1010


comprising at least one empty charging device position, another key feature of the

FIG. 7

rotatable charging apparatus


7000


is its ability to rotate about its axis to thereby selectively position the at least one empty charging device position to face the proximately-located photosensitive element


2000


that is moving in a process direction


2001


.




Accordingly, in another embodiment, the controller


3000


is arranged to control the rotatable charging apparatus


7000


in accordance with a second process


900


as depicted in FIG.


9


.




Referring now to

FIG. 9

, as depicted therein, the process starts at step


901


, and then proceeds to step


903


.




In step


903


, the process determines when a power-down condition exists in the printing machine


700


. When step


903


determines that a power-down condition exists, the process goes to step


907


. Otherwise, after step


903


, the process goes to step


905


.




In step


905


, the process determines when a hard-stop condition exists in the printing machine


700


. In one embodiment, the hard-stop condition comprises a paper jam, or the like. When step


905


determines that a hard-stop condition exists, the process goes to step


907


. Otherwise, after step


905


, the process goes to step


909


.




In step


907


, the process rotates the rotatable charging apparatus from the current charging device to the at least one empty charging device position to face the photosensitive element


2000


. In the rotatable charging apparatus


10


of

FIGS. 1-3

, this step


907


is equivalent to rotating the rotatable charging apparatus


10


to the at least one apparatus surface


18


of the plural apparatus surfaces


11


-


18


that is devoid of a charging device. Also, in the rotatable charging apparatus


1010


of

FIGS. 4-6

, this step


907


is equivalent to rotating the rotatable charging apparatus


1010


to the at least one apparatus position


1018


of the plural apparatus surfaces


1011


-


1018


that is devoid of a charging device. After step


907


, the process goes to step


909


.




In step


909


, the process ends.




Still referring to the second process


900


of

FIG. 9

, it will be understood that, in accordance with step


903


, it is desirable to rotate the rotatable charging apparatus


7000


from its current charging device to the at least one empty charging device position facing the photoreceptor


2000


during a power-down condition in the printing machine


700


to prevent Nitrous Oxide substances emitted from the current charging device from depositing on the photoreceptor


2000


and thereby damaging it. Also, it will be further understood that, in further accordance with step


903


, it is further desirable to rotate the rotatable charging apparatus


7000


from the current charging device to the at least one empty charging device position facing the photoreceptor


2000


during a power-down condition in the printing machine


700


to prevent any heat emitted from the heater in the current charging device from facing the photoreceptor


2000


and thereby potentially damaging it.




Still referring to the second process


900


of

FIG. 9

, it will be understood that, in accordance with step


905


, it is desirable to rotate the rotatable charging apparatus from the current charging device to the at least one empty charging device position facing the photoreceptor


2000


during a hard-stop condition in the printing machine


700


to prevent heat emitted by the current charging device from damaging the photoreceptor


2000


or causing the toner to start blocking and becoming sticky and hard to transfer.




In still another embodiment, the controller


3000


is arranged to control the rotatable charging apparatus


7000


in accordance with the first process


800


as depicted in FIG.


8


and also in accordance with the second process


900


as depicted in FIG.


9


.




In summary, there has been disclosed rotatable charging apparatus (

FIGS. 1-3

element


10


or

FIGS. 4-6

element


1000


) comprising an apparatus length (


31


or


1031


) extending between a first end (


21


or


1021


) and a second end (


22


or


1022


) and centered about an axis (


1


or


1001


) parallel to the apparatus length, with plural charging devices (


110


-


170


or


1110


-


1170


) fixed to an apparatus periphery (


90


or


1090


) surrounding the axis, the rotatable charging apparatus rotatable about the axis to thereby selectively position any charging device to face a proximate photosensitive element


2000


.




Also, there has been disclosed a printing machine


700


comprising rotatable charging apparatus (

FIGS. 1-3

element


10


or

FIGS. 4-6

element


1000


), the rotatable charging apparatus comprising an apparatus length (


31


or


1031


) extending between a first end (


21


or


1021


) and a second end (


22


or


1022


) and centered about an axis (


1


or


1001


) parallel to the apparatus length, with plural charging devices (


110


-


170


or


1110


-


1170


) fixed to an apparatus periphery (


90


or


1090


) surrounding the axis, the rotatable charging apparatus rotatable about the axis to thereby selectively position any charging device to face a proximate photosensitive element


2000


.




As disclosed, the printing machine


700


is arranged for rotating (step


807


) the rotatable charging apparatus (


10


or


1000


) from a current charging device to a new charging device facing the photosensitive element


2000


when a total number of hours of operation of the current charging device exceeds a fixed threshold (step


803


).




Also as disclosed, the printing machine


700


is further arranged for rotating (step


807


) the rotatable charging apparatus (


10


or


1000


) from the current charging device to the new charging device when a problem exists with the current charging device (step


805


).




Also as disclosed, the printing machine


700


is further arranged for rotating (step


907


) the rotatable charging apparatus (


10


or


1000


) from a current charging device to the at least one apparatus surface devoid of a charging device facing the photosensitive element when a power-down condition exists (step


903


).




Also as disclosed, the printing machine


700


is further arranged for rotating (step


907


) the rotatable charging apparatus (


10


or


1000


) from the current charging device to the at least one apparatus surface devoid of a charging device when a hard-stop condition exists (step


905


).




Some advantages of the rotatable charging apparatus, in accordance with the present invention, are now discussed.




While the life goal for the solid-state charger may be, for example, only 300 hours, however, the present invention configures multiple solid-state charger units in the disclosed configurations of

FIGS. 1-6

, or equivalents thereof, to significantly increase product run times. As a result, the rotatable charging apparatus, in accordance with the present invention, presents over-all dimensions that are significantly less than the previous single equivalent discorotron unit. In one embodiment, for example, the rotatable charging apparatus, in accordance with the present invention, comprises an apparatus width (corresponding to

FIGS. 1-3

element


31


and

FIGS. 4-6

element


1031


) of about 20 mm or less, and an apparatus length (corresponding to

FIGS. 1-3

element


32


and

FIGS. 4-6

element


1032


) of 300 mm.




Further, the rotatable charging apparatus, in accordance with the present invention, offers good voltage-sensitive charging performance.




Moreover, the rotatable charging apparatus, in accordance with the present invention, offers lower ozone generation, extensibility across volume bands, and low audible noise.




Furthermore, the rotatable charging apparatus, in accordance with the present invention, is scalable to larger process widths.




Also, the rotatable charging apparatus, in accordance with the present invention, offers potential coronode redundancy for increased charge performance and reliability. Thus, by increasing the number of solid-state chargers available on a single rotatable charging apparatus, the time between repairs is increased. For example, based on a first assumption that the rotatable charging apparatus, in accordance with the present invention, is arranged with seven (7) solid-state chargers, and further based on a second assumption that each of the seven (7) solid-state chargers comprise a 2000-hour operating life, then the time between replacements of the rotatable charging apparatus is expected to be about 583 days. Moreover, in the aforementioned example, if each of the seven (7) solid-state chargers comprise a 300-hour operating life, then the time between replacements of the rotatable charging apparatus is expected to be about 87.5 days.




While various embodiments of a rotatable charging apparatus and printing machine including the same, in accordance with the present invention, have been described hereinabove, the scope of the invention is defined by the following claims.



Claims
  • 1. A rotatable charging apparatus comprising an apparatus length extending between a first end and a second end and centered about an axis parallel to the apparatus length, with plural charging devices fixed to an apparatus periphery surrounding the axis, the rotatable charging apparatus rotatable about the axis to thereby selectively position any charging device to face a proximate photosensitive element, each charging device comprising a solid-state charger, the first and second ends generally being circular-shaped.
  • 2. A rotatable charging apparatus comprising an apparatus length extending between a first end and a second end and centered about an axis parallel to the apparatus length, with plural charging devices fixed to an apparatus periphery surrounding the axis, the rotatable charging apparatus rotatable about the axis to thereby selectively position any charging device to face a proximate photosensitive element, each charging device comprising a solid-state charger, the apparatus periphery comprising plural apparatus surfaces with each charging device fixed to one of the plural apparatus surfaces, at least one apparatus surface being devoid of a charging device.
  • 3. The rotatable charging apparatus of claim 2, the first and second ends respectively forming first and second polygons, each polygon with a fixed number (“N”) of sides.
  • 4. The rotatable charging apparatus of claim 3, N being 8.
  • 5. The rotatable charging apparatus of claim 4, each charging device comprising a charging device width of about 5 mm.
  • 6. The rotatable charging apparatus of claim 4, each charging device comprising a charging device width of about 7 mm.
  • 7. A printing machine comprising a rotatable charging apparatus, the rotatable charging apparatus comprising an apparatus length extending between a first end and a second end and centered about an axis parallel to the apparatus length, with plural charging devices fixed to an apparatus periphery surrounding the axis, the rotatable charging apparatus rotatable about the axis to thereby selectively position any charging device to face a proximate photosensitive element, each charging device comprising a solid-state charger, the first and second ends generally being circular-shaped.
  • 8. A printing machine comprising a rotatable charging apparatus, the rotatable charging apparatus comprising an apparatus length extending between a first end and a second end and centered about an axis parallel to the apparatus length, with plural charging devices fixed to an apparatus periphery surrounding the axis, the rotatable charging apparatus rotatable about the axis to thereby selectively position any charging device to face a proximate photosensitive element, each charging device comprising a solid-state charger, the apparatus periphery comprising plural apparatus surfaces with each charging device fixed to one of the plural apparatus surfaces, at least one apparatus surface being devoid of a charging device.
  • 9. The printing machine of claim 8, the first and second ends respectively forming first and second polygons, each polygon with a fixed number (“N”) of sides.
  • 10. The printing machine of claim 9, N being 8.
  • 11. The printing machine of claim 8, arranged for rotating the rotatable charging apparatus from a current charging device to the at least one apparatus surface devoid of a charging device facing the photosensitive element when a power-down condition exists.
  • 12. The printing machine of claim 11, further arranged for rotating the rotatable charging apparatus from the current charging device to the at least one apparatus surface devoid of a charging device when a hard-stop condition exists.
  • 13. A printing machine comprising a rotatable charging apparatus, the rotatable charging apparatus comprising an apparatus length extending between a first end and a second end and centered about an axis parallel to the apparatus length, with plural charging devices fixed to an apparatus periphery surrounding the axis, the rotatable charging apparatus rotatable about the axis to thereby selectively position any charging device to face a proximate photosensitive element, each charging device comprising a solid-state charger, arranged for rotating the rotatable charging apparatus from a current charging device to a new charging device facing the photosensitive element when a total number of hours of operation of the current charging device exceeds a fixed threshold.
  • 14. The printing machine of claim 13, further arranged for rotating the rotatable charging apparatus from the current charging device to the new charging device when a problem exists with the current charging device.
INCORPORATION BY REFERENCE OF ANOTHER U.S. PATENT

The applicant hereby incorporates by reference the disclosure of Richard F. Bergen et al., U.S. Pat. No. 5,563,688, “Charging device for charging in one of a plurality of predefined image areas on a surface of an imaging member,” issued Oct. 8, 1996, verbatim and with the same effect as though such disclosure were fully and completely set forth herein.

US Referenced Citations (5)
Number Name Date Kind
4056723 Springett et al. Nov 1977
4734722 Maczuszenko et al. Mar 1988
5530526 Kleckner et al. Jun 1996
5563688 Bergen et al. Oct 1996
6210848 Nagai et al. Apr 2001