FIELD OF THE INVENTION
[0001] The present invention relates to image forming and image transfer apparatus especially
for use in electrostatic imaging using a sheet type photoreceptor.
BACRGROUND OF THE INVENTION
[0002] Organic photoreceptor materials for use in toner imaging are well known. In some
systems the organic photoreceptor is coated onto a drum or endless belt on which an
electrostatic image is formed. In other systems a sheet of photoreceptor material
is mounted onto a drum to provide the same function.
SUMMARY OF THE INVENTION
[0003] The present invention seeks to provide, in a first aspect thereof, improved image
forming apparatus utilizing a new sheet photoreceptor configuration.
[0004] The present invention further seeks to provide, in a second aspect thereof, an improved
sheet photoreceptor for use in such apparatus as defined in present claim 1.
[0005] There is thus provided, in accordance with a preferred embodiment of the invention
imaging apparatus including:
a substantially rectangular organic photoreceptor sheet including a backing layer,
a conductive layer and a photoconductive layer, wherein along one edge of the sheet
there is an exposed conductive area, preferably an exposed portion of the conductive
layer;
a drum having a longitudinal cavity formed therein and including a slot formed between
the cavity and the cylindrical surface of the drum into which the one edge of the
photoreceptor sheet is inserted; and
a rotatable element within the cavity which, in a locking position, presses the sheet,
and preferably the conductive area thereof against a wall of the cavity, fixedly and
removably holding the photoreceptor sheet in place, and providing an electrical connection
between the conductive layer and the drum.
[0006] Alternatively, the conductive area is pressed against the rotatable element.
[0007] In a preferred embodiment of the invention, the drum is at substantially ground electrical
potential.
[0008] In a preferred embodiment of the invention on a portion of the photoreceptor sheet,
along a second edge thereof opposite the one edge, both the photoconductive and conductive
layers are not present: and wherein the portion of the photoreceptor sheet overlies
the slot.
[0009] Preferably, the chargeable photoreceptor includes a dust masking layer, preferably
of paper, between the backing layer and the drum. Preferably, the dust absorbing is
attached to the backing layer adjacent to the slot.
[0010] There is further provided, in accordance with a preferred embodiment of the invention,
a substantially rectangular organic photoreceptor sheet including a backing layer,
a conductive layer and a photoconductive layer wherein along one edge thereof the
photoconductive and the conductive layers are not present, such that the backing layer
extends beyond the edge of the photoconductive and conductive layers.
[0011] Preferably the photoreceptor sheet includes a dust masking layer, preferably of paper,
adjacent the backing layer. Preferably, the dust absorbing is attached to the backing
layer only along an edge of the dust absorbing layer. Preferably the dust masking
layer is attached adjacent to and displaced from an edge of the photoreceptor opposite
the one edge thereof at which the photoconductive and the conductive layers are not
present.
BRIEF DESCRIPTION OF THE DRAWINGS
[0012] The present invention will be understood and appreciated more fully from the following
detailed description, taken in conjunction with the drawings in which:
Fig. 1A and 1B are cross-sectional, simplified, overall and expanded, partial drawings,
respectively of a drum on which a photoreceptor is mounted, showing a mounting method
for photoreceptors in accordance with a preferred embodiment of the invention;
Figs. 1C and 1D show an alternative method for mounting photoreceptors in respective
open and gripping configurations;
Fig. 2A and 2B are respective top and side views of a photoreceptor in accordance
with a preferred embodiment of the invention;
Figs. 2C and 2D are cross-sectional partial side views of the photoreceptor of Figs.
2A and 2B;
Fig. 2E is a cross-sectional partial side view of a photoreceptor in accordance with
another, preferred, embodiment of the present invention;
Fig. 3A and 3B are cross-sectional partial side views of two, respective, types of
insulated-edge photoreceptors, constructed in accordance with a further preferred
embodiment of the present invention; and
Figs. 4A, 4B, and 4C are respective side view, top view, and side view illustrations
of three, respective, steps in a preferred method of forming the insulated edge photoreceptor
of Fig. 3A.
DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS
[0013] A novel photoreceptor sheet 12 and apparatus and a method for mounting the sheet
on a drum 10 are shown in Figs. 1A - 1D and 2A - 2D.
[0014] Photoreceptor sheet 12 is preferably mounted on drum 10 using the mechanisms shown
in Figs. 1A and 1B or 1C and 1D. As shown most clearly in Fig. 1B, one end of photoconductive
sheet is inserted into a slot 140 which forms the entryway to a cavity 142 formed
in drum 10. An eccentric cylindrical cam 144 which is situated in the cavity can be
rotated to one of two positions. With the cam in a first position shown by dotted
lines in Fig. 1B, the photoreceptor can be inserted into the slot and between the
cam and a wall of cavity 142. After the photoreceptor is in the position shown in
Fig. 1B, cam 144 is rotated to the position shown by the solid lines, thereby pressing
the cam against the photoreceptor and holding it in position on the drum.
[0015] Figs. 1C and 1D show a rotating member 20 having a resilient element 22, such as
a row of spring fingers attached thereto and facing toward the outside of the drum.
When the rotating member is in an open position as shown in Fig. 1C, the photoreceptor
can be inserted into slot 140 past resilient element 22. Preferably, resilient element
22 guides the inserted end of the photoreceptor to position 141 which acts to assure
that the photoreceptor is positioned without skew relative to the rotating direction.
[0016] When the rotating element is turned as shown in Fig. 1D the resilient fingers press
against the photoreceptor and hold it firmly against the outer wall of cavity 142.
[0017] A preferred embodiment of the photoreceptor sheet 12 which is especially suitable
for mounting in accordance with the method illustrated in Figs. 1A to 1D is shown
in Figs. 2A-2D.
[0018] Photoreceptor sheet 12 consists essentially of an especially configured photoreceptor
and an attached sheet of paper or other dust encasing material such as rubber. As
shown most clearly in Figs. 2B-2D, a central portion 150 of photoreceptor sheet 12
comprises four layers, a paper layer 151, which is shown bottom most on Figs. 2B-2D
and is in contact with drum 10, a backing layer 152, such as of Mylar or the like
adjacent to the paper layer, preferably attached thereto and preferably not attached
thereto over its entire surface, a conducting layer 154 overlying the backing layer
and a photoconductive layer 156 overlying the conducting layer. In general the photoconductive
layer comprises a charge transport layer and a charge generation layer; however, these
are referred to herein as a "photoconductive layer" for simplicity of the discussion,
since the exact construction of the photoconductive layer or layers does not form
a part of the present invention. A preferred photoreceptor is, for example, Emerald
2 (manufactured by Lexmark
®). To improve compatibility of the photoreceptor when it is used with liquid toner,
the photoconductor should preferably be treated by one of the treatments specified
in PCT publication WO 91/17485 which corresponds to copending U.S. publication 5,376,491.
[0019] In general these applications describe several processes. In one process, the photoreceptor
sheet is mounted on a drum with the photoconductive surface facing outwards. The sheet
is subjected to heat treatment which removes stress from the photoconductive layer
without removing it from the backing layer. The photoreceptor is now cooled, without
removing it from the drum. When the photoreceptor is removed from the drum, the photoconductive
layer is in compression and the backing layer is in tension.
[0020] In a second process the photoreceptor sheet is subjected to tension and heated to
a temperature at which the photoconductive layer is stress released but at which the
backing is not stress released. The sheet is cooled and then the tension is removed.
This process also results in a photoreceptor sheet in which the photoconductive layer
is in compression and the backing layer is in tension.
[0021] In a third process the surface of the photoconductive layer is chemically treated
to remove stress from the layer and make it more plastic or elastic than it previously
was. Preferably materials such as cyclohexanone are used to chemically treat the photoconductive
layer.
[0022] What should be noted in Figs. 1B-1D is that not all of the layers extend to the ends
of photoreceptor sheet 12. In particular, the end of the sheet which is inserted into
slot 140 (the "leading edge" of the sheet), as shown in Figs. 1B-1D, has only two
layers, i.e., backing layer 152 and conducting layer 154. This assures that the conducting
layer, when pressed against the interior of cavity 140 by cam 144 or member 22, will
make good electrical contact with the cavity wall. This provides convenient grounding
of the conductive layer, even when the backing layer and the paper layer are not conducting.
[0023] Alternatively, the photoreceptor can be provided with a conductive edge which is
electrically connected with the conductive layer and either the cavity wall or resilient
member 22, or both.
[0024] The paper layer, as indicated above, is not attached to the back of the backing layer
over the length of the photoreceptor. However, in a preferred embodiment of the invention,
the paper is attached to the backing layer near the leading edge of the photoreceptor
and at the end of the paper, i.e., at reference numeral 158. The function of the paper
layer is to reduce the effect of dust or other particles which may be on the drum
(or possibly between the photoreceptor and the paper) from effecting the imaging process
by causing pressure points on the surface of the photoreceptor. The optimum thickness
of the paper layer has been found, for the particular photoreceptor described above,
to be between about 50 micrometers and 300 micrometers and a soft, open weave paper
such as Nordland Woodtree uncoated white bond printing paper (120g/m
2, =150 micrometers thick, manufactured by Nordland, Germany) is preferred.
[0025] The other end of the photoreceptor (its trailing edge), which is shown in detail
in Fig. 2D preferably comprises only the backing layer, and, as shown in Figs. 1B
-1D, the backing layer extension is long enough to overlay slot 140 so as to avoid
liquid toner entering cavity 142. Further, the outer surface of drum 10 is shaped
near slot 140 (at reference numeral 160) to provide a slope so that the contact between
the photoreceptor and surfaces which it contacts is smooth, i.e., such that the overall
diameter of the drum and the photoreceptor and, if present, the overlaying trailing
edge, remains independent of the angular position on the drum.
[0026] All the layers other than the backing layer are removed at the trailing edge mainly
to obviate any chance that the conducting surface will touch a charging device such
as a scorotron which is normally present in electrostatic imaging apparatus. Due to
the absence of grounded conducting layer 154 at the trailing edge of the photoreceptor
sheet, the generally dielectric backing layer 152 remains substantially constantly
charged, at the trailing edge, when the photoreceptor sheet is in operative use. This
results in electrostatic attraction between drum 10 and the charged trailing edge
of sheet 12, assisting in the adherence of sheet 12 to drum 10. It should be noted
that sheet 12 is generally not attached to drum 10 by mechanical means, other than
at the leading edge, to account for possible variations in the length of sheet 12
during operation. The electrostatic force provided by the dielectric trailing edge
of sheet 12 allows circumferential relative motion between sheet 12 and drum 10.
[0027] Finally, if the photoreceptor is pressed against another surface, the trailing edge
of the photoreceptor is cut at a slight angle to square, of about 1 in 35. This angle
is used to provide a smooth transition of contact, at the edge, for a cleaner blade,
used to clean untransferred toner from the photoreceptor, prior to the next imaging
cycle. A photoreceptor sheet having square cut ends or having one or both edges cut
at a slight angle is referred to herein as a "substantially rectangular" photoreceptor
sheet. All edges and transitions are preferably smooth without jagged margins.
[0028] For clarity, the overlapping end of the photoreceptor sheet is not shown in Figs.
1C and 1D.
[0029] The dimensions of the leading and trailing edges of the photoreceptor can be varied
to suit the particular application. The present inventors have found that the leading,
conductive edge (inserted into slot 140) of the photoreceptor is preferably about
13 mm wide and the trailing edge (for overlap) is preferably about 20 mm wide.
[0030] For reference the direction of rotation of drum 10 is shown by an arrow 162.
[0031] To avoid possible voltage breakdown, for reasons described in detail below, it is
generally desired that the trailing edge of photoconductive layer 156 extend beyond
the trailing edge of conductive layer 154 or, at least, that the two edges be substantially
aligned, as shown in Fig. 2D. Unfortunately, these desired arrangements of the trailing
edges have been found to be extremely difficult to implement. Fig. 2E illustrates
an alternative, more practical, embodiment of the trailing edge of photoreceptor sheet
12 in which conductive layer 154 extends slightly beyond photoreceptor layer 156.
[0032] The above described photoreceptor sheet 12 may be used in any known electrostatic
imaging device. However, in a preferred embodiment of the present invention, liquid
toner imaging apparatus is used, preferably of the type described in U.S. Patent publication
5,745,829 , filed January 11, 1995. In such imaging apparatus, an electrically biased
squeegee roller (not shown) is used for squeegeeing a layer of liquid toner which
is developed onto the photoreceptor surface. The squeegee roller is typically electrically
biased, preferably to a negative voltage of 1300-1600 Volts, and urged against the
photoreceptor with a predetermined pressure, typically approximately 90 grams per
centimeter along the length of the squeegee roller. This provides both electrical
and mechanical squeegeeing of the layer of liquid toner on the photoreceptor.
[0033] It has been found that the large difference in electric potential between the squeegee
roller and conductive layer 154 of sheet 12, which is typically grounded as described
above, may result in electrical breakdown at the trailing edge of layer 154. This
breakdown of voltage may occur during actual contact between the squeegee roller and
the trailing edge of layer 154 or by arcing between the squeegee roller and the conductive
layer. Actual contact between the edge of layer 154 and the squeegee roller is possible,
particularly in the embodiment of Fig. 2E, due to slight compliance of the generally
resilient sheet 12 when urged by the generally rigid squeegee roller.
[0034] It is appreciated that the above described breakdown results in gradual, accumulative,
deterioration of both photoreceptor surface 12 and the squeegee roller. Consequently,
the cumulative damage to the squeegee roller results in degraded performance of the
imaging apparatus due to less effective and inhomogeneous squeegeeing of the liquid
toner on the photoreceptor surface. Thus, in a preferred embodiment of the present
invention, the trailing edge of layer 154 is insulated to prevent breakdown, as described
in detail below. It should be noted that insulation of the trailing edge of layer
154 is preferred also in the desired, yet not readily implemented, arrangement (not
shown in the drawings) in which the trailing edge of layer 156 extends beyond the
trailing edge of layer 154.
[0035] Figs. 3A and 3B which schematically illustrate two types of trailing edges, analogous
to the two types of trailing edges shown in Figs. 2D and 2E, respectively, whose conductive
layers 154 are electrically insulated at edges 170 and 172, respectively, in accordance
with a preferred embodiment of the present invention. According to this preferred
embodiment, a layer 175 of, preferably dielectric, insulating material is applied
to trailing edge 170 (Fig. 3A) or trailing edge 172 (Fig. 3B), preventing electrical
breakdown thereat. To ensure complete coverage of edge 170 or edge 172, layer 175
preferably extends slightly beyond edges 170 or 172, both on photoreceptor layer 156
and on backing layer 152. The extension of layer 175 on layer 156 is indicated by
reference numeral 176. For imaging systems using a scraper, such as a doctor blade,
extension 176 is preferably made extremely thin to avoid damage to the scraper. This
is because the scrapers used by such imaging systems are generally extremely sensitive
to protrusions in the direction of scraping.
[0036] In a preferred embodiment of the invention, insulating layer 175 is formed of HumiSeal
® type 1A24, a vinyl-modified-epoxy based dielectric material, available from Columbia
Chase Corporation, New York, USA. This insulating material is provided in a solids
concentration of 20-24 percent by weight and a viscosity of 100-130 centipoise and
has a drying/handling time of 15 minutes and a recommended curing time of 24 hours
in room temperature. The material can be thinned, for example using acetone, to adjust
the viscosity of the material for a given method of application. The cured layer is
generally transparent, highly adhesive, very flexible and very durable to varying
temperature and humidity conditions. The cured layer has a dielectric withstand voltage
of approximately 3,900 Volts, a dielectric constant of approximately 2.88 at 1MHz
and 25 degrees centigrade, a dissipation factor of 0.002, an insulation resistance
of approximately 350,000,000 Megohms and a moisture resistance of approximately 30,000
Megohms. The material is also highly resistant to solvents and various chemicals.
[0037] Although the use of HumiSeal type 1A24 is preferred, layer 175 may be formed of any
other suitable dielectric material. For example, layer 175 may be formed of HumiSeal
type 1A33, a polyurethane based dielectric material, or the layer may be formed of
a material based on polyvinyl alcohol (88% hydrolyzed).
[0038] Reference is now made to Figs. 4A-4C which schematically illustrate a preferred method
of applying layer 175 to edge 170, by metered brushing. It should be appreciated that
the same application method can be used for applying layer 175 to edge 172 if sheet
12 is constructed as in Fig. 2E. Although the method of Figs. 4A-4C has been found
effective, it should be appreciated that other application methods, such as spraying
or dipping, may also suitable.
[0039] Fig. 4A illustrates a first step in the metered application method, in which a series
of drops 178 of the insulating material are guided along the surface of an application
blade 177 to a portion of backing layer 152 close to edge 170 of layer 154. Drops
178 are preferably separated from edge 170 by a gap of approximately 3-4 millimeters.
The series of drops formed on layer 152 in parallel with edge 170 is shown in Fig.
4B. Sheet 12 is preferably positioned on a detachable base layer, preferably formed
of paper or the like, which extends beyond sheet 12 at least at the portion indicated
by reference numeral 179. This enables application of at least one drop of insulating
outside the boarders of sheet 12, allowing complete coverage of edge 170 by the brushing
described below.
[0040] Fig. 4C illustrates a preferred brushing technique, wherein a smooth and straight
edge of a brushing sheet 180, preferably formed of a resilient material, is urged
against the sheet 12 and moved in a brushing motion along edge 170. Brushing sheet
180 may be formed of any suitable rubber or plastic material having a suitable resilience
and surface smoothness. In one preferred embodiment of the invention, brushing sheet
180 is formed of the material used for the intermediate transfer blanket described
in U.S. Patent publication 5,745,829. In the configuration of drops 178 shown in Fig.
4B, the brushing action is from bottom to top, starting from region 179 outside sheet
12.
[0041] To ensure complete coverage of edge 170, the total amount of insulating material
in drops 178 is equal to at least the volume enclosed by the trailing edges of layers
154 and 156, protruding layer 152 and the brushing plane defined by the action of
brushing sheet 180. The resilience of the edge of brushing sheet 180 ensures gap-free
application of insulating layer 175 to edge 170 and maintains the thickness of extension
176 of layer 175 at a minimum.
1. A substantially rectangular organic photoreceptor sheet comprising a backing layer,
a conductive layer and a photoconductive layer wherein along one edge thereof the
photoconductive and the conductive layers are not present such that the backing layer
extends beyond the edge of the photoconductive and conductive layers.
2. An organic photoreceptor sheet according to claim 1 wherein the edge of the conductive
layer is coated with a layer of insulating material.
3. A photoreceptor sheet according to claim 2 wherein the insulating material comprises
a dielectric material.
4. A photoreceptor sheet according to any of the preceding claims wherein the respective
edges of the photoconductive layer and the conductive layer are aligned.
5. A photoreceptor sheet according to any of the preceding claims wherein the edge of
the conductive layer extends slightly beyond the respective edge of the photoconductive
layer.
6. A photoreceptor sheet according to any of the preceding claims wherein the edge of
the photoreceptor at which the photoconductive layer and the conductive layer is not
present is somewhat out of square with adjoining edges of the photoreceptor.
7. A photoreceptor sheet according to any of the preceding claims wherein along a second
edge thereof opposite the one edge, the photoconductive layer is not present such
that the conductive layer is exposed forming a conductive area.
8. A photoreceptor sheet according to any of the preceding claims wherein only the backing
layer extends beyond the conductive and photoconductive layers along only one edge
thereof.
9. A photoreceptor sheet according to any of claims 1-8 and further comprising a dust
masking layer adjacent the backing layer.
10. A photoreceptor sheet according to claim 9 wherein the dust making layer is a paper
layer.
11. A photoreceptor sheet according to claim 9 or claim 10 wherein the dust masking layer
is attached to the backing layer only along an edge of the dust masking layer.
12. A photoreceptor sheet according to any of claims 9-11 wherein the dust masking layer
is attached adjacent to and displaced from an edge of the photoreceptor opposite an
edge thereof at which the photoconductive layer and the conductive layers are not
present.
13. Imaging apparatus comprising:
a substantially rectangular organic photoreceptor sheet comprising a backing layer,
a conductive layer and a photoconductive layer, wherein along one edge of the sheet
there is an exposed conductive area;
a drum having longitudinal cavity formed therein and including a slot formed between
the cavity and the cylindrical surface of the drum into which the one edge of the
photoreceptor sheet is inserted; and
a rotatable element within the cavity which, in a locking position, presses the sheet
against a wall of the cavity, fixedly and removably holding the photoreceptor sheet
in place and providing an electrical connection between the conductive layer and the
drum.
14. Apparatus according to claim 13 wherein the conductive area is an exposed portion
of the conductive layer, the photoconductive layer being absent.
15. Apparatus according to claim 13 or claim 15 wherein the conductive area is pressed
against the wall of the cavity.
16. Apparatus according to claim 13 or claim 14 wherein the conductive area is pressed
against the rotatable element.
17. Imaging apparatus according to any of claims 13-16 wherein the drum is at substantially
ground electrical potential.
18. Imaging apparatus according to any of claims 13-17 wherein, on a portion of the photoreceptor
sheet, along a second edge thereof opposite the one edge, both the photoconductive
and conductive layers are not present and wherein said portion of the photoreceptor
sheet overlies the slot.
19. Imaging apparatus according to any of claims 13-18 wherein the chargeable photoreceptor
comprises a dust masking layer between the backing layer and the drum.
20. Imaging apparatus according to claim 19 wherein the dust masking layer is attached
to the backing layer adjacent to the slot.
21. Imaging apparatus according to any of claims 13-20 wherein the photoreceptor sheet
comprises a photoreceptor sheet according to any of claims 1-12.
22. Imaging apparatus according to any of claims 13-21 wherein only the one edge has an
exposed conductor.
1. Eine im Wesentlichen rechteckige Lage eines organischen Photorezeptors, die eine Unterstützungsschicht,
eine leitfähige Schicht und eine photoleitfähige Schicht aufweist, wobei entlang einer
Kante desselben die photoleitfähige und die leitfähige Schicht nicht vorhanden sind,
derart, dass sich die Unterstützungsschicht über die Kante der photoleitfähigen und
der leitfähigen Schicht hinaus erstreckt.
2. Eine Lage eines organischen Photorezeptors gemäß Anspruch 1, bei der die Kante der
leitfähigen Schicht mit einer Schicht eines isolierenden Materials beschichtet ist.
3. Eine Photorezeptorlage gemäß Anspruch 2, bei der das isolierende Material ein dielektrisches
Material aufweist.
4. Eine Photorezeptorlage gemäß einem der vorhergehenden Ansprüche, bei der die jeweiligen
Kanten der photoleitfähigen Schicht und der leitfähigen Schicht ausgerichtet sind.
5. Eine Photorezeptorlage gemäß einem der vorhergehenden Ansprüche, bei der die Kante
der leitfähigen Schicht sich etwas über die jeweilige Kante der photoleitfähigen Schicht
hinaus erstreckt.
6. Eine Photorezeptorlage gemäß einem der vorhergehenden Ansprüche, bei der die Kante
des Photorezeptors, an der die photoleitfähige Schicht und die leitfähige Schicht
nicht vorhanden sind, zu angrenzenden Kanten des Photorezeptors nicht ganz rechtwinkelig
ist.
7. Eine Photorezeptorlage gemäß einem der vorhergehenden Ansprüche, bei der entlang einer
zweiten Kante derselben gegenüber der einen Kante die photoleitfähige Schicht nicht
vorhanden ist, derart, dass die leitfähige Schicht freigelegt ist, wobei ein leitfähiger
Bereich gebildet ist.
8. Eine Photorezeptorlage gemäß einem der vorhergehenden Ansprüche, bei der sich lediglich
die Unterstützungsschicht entlang lediglich einer Kante derselben über die leitfähige
und die photoleitfähige Schicht hinaus erstreckt.
9. Eine Photorezeptorlage gemäß einem Ansprüche 1-8, die ferner eine Staubmaskierungsschicht
benachbart zu der Unterstützungsschicht aufweist.
10. Eine Photorezeptorlage gemäß Anspruch 9, bei der die Staubmaskierungsschicht eine
Papierschicht ist.
11. Eine Photorezeptorlage gemäß Anspruch 9 oder Anspruch 10, bei der die Staubmaskierungsschicht
lediglich entlang einer Kante der Staubmaskierungsschicht an der Unterstützungsschicht
angebracht ist.
12. Eine Photorezeptorlage gemäß einem der Ansprüche 9-11, bei der die Staubmaskierungsschicht
benachbart zu und verlagert von einer Kante des Photorezeptors gegenüber einer Kante
desselben angebracht ist, an der die photoleitfähige Schicht und die leitfähigen Schichten
nicht vorhanden sind.
13. Bilderzeugungsvorrichtung, die folgende Merkmale aufweist:
eine im Wesentlichen rechteckige Lage eines organischen Photorezeptors, die eine Unterstützungsschicht,
eine leitfähige Schicht und eine photoleitfähige Schicht aufweist, wobei sich entlang
einer Kante der Lage ein freiliegender leitfähiger Bereich befindet;
eine Trommel, in der ein longitudinaler Hohlraum gebildet ist und die einen Schlitz
umfasst, der zwischen dem Hohlraum und der zylindrischen Oberfläche der Trommel gebildet
ist und in den die eine Kante der Photorezeptorlage eingebracht ist; und
ein drehbares Element innerhalb des Hohlraums, das in einer Verriegelungsstellung
die Lage gegen eine Wand des Hohlraums drückt, die Photorezeptorlage fest und entfernbar
in Position hält und eine elektrische Verbindung zwischen der leitfähigen Schicht
und der Trommel liefert.
14. Vorrichtung gemäß Anspruch 13, bei der der leitfähige Bereich ein freiliegender Abschnitt
der leitfähigen Schicht ist, wobei die photoleitfähige Schicht nicht vorhanden ist.
15. Vorrichtung gemäß Anspruch 13 oder Anspruch 14, bei der der leitfähige Bereich gegen
die Wand gedrückt ist.
16. Vorrichtung gemäß Anspruch 13 oder Anspruch 14, bei der der leitfähige Bereich gegen
das drehbare Element gedrückt ist.
17. Bilderzeugungsvorrichtung gemäß einem der Ansprüche 13-16, bei der die Trommel sich
im Wesentlichen bei einem elektrischen Massepotential befindet.
18. Bilderzeugungsvorrichtung gemäß einem der Ansprüche 13-17, bei der an einem Abschnitt
der Photorezeptorlage entlang einer zweiten Kante derselben gegenüber der einen Kante
sowohl die photoleitfähige als auch die leitfähige Schicht nicht vorhanden sind und
bei der der Abschnitt der Photorezeptorlage den Schlitz überlagert.
19. Bilderzeugungsvorrichtung gemäß einem der Ansprüche 13-18, bei der der aufladbare
Photorezeptor eine Staubmaskierungsschicht zwischen der Unterstützungsschicht und
der Trommel aufweist.
20. Bilderzeugungsvorrichtung gemäß Anspruch 19, bei der die Staubmaskierungsschicht an
der Unterstützungsschicht benachbart zu dem Schlitz angebracht ist.
21. Bilderzeugungsvorrichtung gemäß einem Ansprüche 13-20, bei der die Photorezeptorlage
eine Photorezeptorlage gemäß einem der Ansprüche 1 bis 12 aufweist.
22. Bilderzeugungsvorrichtung gemäß einem der Ansprüche 13-21, bei der lediglich die eine
Kante einen freiliegenden Leiter aufweist.
1. Feuille de photorécepteur organique sensiblement rectangulaire comprenant une couche
de support, une couche conductrice et une couche photoconductrice, dans laquelle,
suivant un bord de celle-ci, les couches photoconductrice et conductrice ne sont pas
présentes de manière que la couche de support s'étende au-delà du bord des couches
photoconductrice et conductrice.
2. Feuille de photorécepteur organique selon la revendication 1, dans laquelle le bord
de la couche conductrice est recouvert avec une couche de matériau isolant.
3. Feuille de photorécepteur selon la revendication 2, dans laquelle le matériau isolant
comprend un matériau diélectrique.
4. Feuille de photorécepteur selon l'une quelconque des revendications précédentes, dans
laquelle les bords respectifs de la couche photoconductrice et de la couche conductrice
sont alignés.
5. Feuille de photorécepteur selon l'une quelconque des revendications précédentes, dans
laquelle le bord de la couche conductrice s'étend légèrement au-delà du bord respectif
de la couche photoconductrice.
6. Feuille de photorécepteur selon l'une quelconque des revendications précédentes, dans
laquelle le bord du photorécepteur au niveau duquel la couche photoconductrice et
la couche conductrice ne sont pas présentes n'est légèrement pas d'équerre avec des
bords contigus du photorécepteur.
7. Feuille de photorécepteur selon l'une quelconque des revendications précédentes, dans
laquelle, suivant un deuxième bord de celle-ci opposé au un bord, la couche photoconductrice
n'est pas présente de sorte que la couche conductrice est exposée en formant une zone
conductrice.
8. Feuille de photorécepteur selon l'une quelconque des revendications précédentes, dans
laquelle seule la couche de support s'étend au-delà des couches conductrice et photoconductrice
suivant seulement un bord de celle-ci.
9. Feuille de photorécepteur selon l'une quelconque des revendications 1 à 8 comprenant
en outre une couche de masquage de poussière adjacente à la couche de support.
10. Feuille de photorécepteur selon la revendication 9, dans laquelle la couche de masquage
de poussière est une couche de papier.
11. Feuille de photorécepteur selon la revendication 9 ou 10, dans laquelle la couche
de masquage de poussière est fixée à la couche de support seulement le long d'un bord
de la couche de masquage de poussière.
12. Feuille de photorécepteur selon l'une quelconque des revendications 9 à 11, dans laquelle
la couche de masquage de poussière est fixée adjacente et décalée par rapport à un
bord du photorécepteur opposé à un bord de celle-ci au niveau duquel les couches photoconductrice
et conductrice ne sont pas présentes.
13. Appareil d'imagerie comprenant :
une feuille de photorécepteur organique sensiblement rectangulaire comprenant une
couche de support, une couche conductrice et une couche photoconductrice, dans laquelle,
suivant un bord de la feuille se trouve une zone conductrice exposée ;
un tambour ayant une cavité longitudinale formée dans celui-ci et comprenant une fente
formée entre la cavité et la surface cylindrique du tambour dans laquelle ledit bord
de la feuille de photorécepteur est inséré ; et
un élément rotatif à l'intérieur de la cavité qui, dans une position de blocage, presse
la feuille contre une paroi de la cavité, en maintenant la feuille de photorécepteur
en place de manière ferme et amovible et en fournissant une connexion électrique entre
la couche conductrice et le tambour.
14. Appareil d'imagerie selon la revendication 13, dans lequel la zone conductrice est
une partie exposée de la couche conductrice, la couche photoconductrice étant absente.
15. Appareil d'imagerie selon la revendication 13 ou 14, dans lequel la zone conductrice
est pressée contre la paroi de la cavité.
16. Appareil d'imagerie selon la revendication 13 ou 14, dans lequel la zone conductrice
est pressée contre l'élément rotatif.
17. Appareil d'imagerie selon l'une quelconque des revendications 13 à 16, dans lequel
le tambour est à un potentiel électrique sensiblement de masse.
18. Appareil d'imagerie selon l'une quelconque des revendications 13 à 17, dans lequel,
sur une partie de la feuille de photorécepteur, suivant un deuxième bord de celle-ci
opposé au premier bord, à la fois les couches photoconductrice et conductrice ne sont
pas présentes et dans lequel ladite partie de la feuille de photorécepteur recouvre
la fente.
19. Appareil d'imagerie selon l'une quelconque des revendications 13 à 18, dans lequel
le photorécepteur chargeable comprend une couche de masquage de poussière entre la
couche de support et le tambour.
20. Appareil d'imagerie selon la revendication 19, dans lequel la couche de masquage de
poussière est fixée à la couche de support adjacente à la fente.
21. Appareil d'imagerie selon l'une quelconque des revendications 13 à 20, dans lequel
la feuille de photorécepteur comprend une feuille de photorécepteur selon l'une quelconque
des revendications 1 à 12.
22. Appareil d'imagerie selon l'une quelconque des revendications 13 à 21, dans lequel
seul le premier bord a un conducteur exposé.