FIELD OF THE INVENTION
[0001] The present invention is directed to an image transfer device for transferring images
of a marking substance, including ink and toner, from an image transfer member to
a recording medium. Moreover the invention is related to a method of removing debris
from the surface of the image transfer member of such image transfer device.
BACKGROUND OF THE INVENTION
[0002] Image reproduction systems, such as printers and copiers, often include an image
transfer device having an image transfer member, usually in the form of a belt or
a drum, for receiving on its surface a marking substance, such as toner or ink, in
image form and for subsequently transferring these images of marking substance in
a transfer zone to a recording medium, such as paper. In an operative state, the image
transfer member is urged against a counter member in the transfer zone while the recording
medium passes therebetween. The transfer may take place by means of pressure, or heat,
or heat and pressure each of them optionally assisted by electrostatic forces and/or
vibrational forces. Particularly in case the marking substance is a toner, the marking
substance must be fixed onto the receiving material in order to render the images
permanent. By applying an appropriate amount of pressure and heat in the transfer
zone, transfer and fixing take place simultaneously. Otherwise a subsequent fixing
step is to be executed. For example, this may be done by feeding the recording medium,
onto which the unfixed marking substance is already deposited, through a fixing zone
where an increased temperature and pressure serve to fix the image permanently to
the recording medium.
In such image transfer devices, contaminants e.g. in the form of residual marking
substance material and/or debris originating from the recording medium and/or other
impurities may build up on the surface of the image transfer member. For instance
when the recording medium is paper or a like fibrous material, debris in the form
of dust and fibres may build up on the image transfer member surface in the region
of the transfer zone. If these contaminants remain on the image transfer member surface,
the efficiency of the image transfer and the quality of the fixing where applicable,
may be affected. Hence, it is desirable to clean the image transfer member surface.
[0003] It is known to provide an endless cleaning member having a tacky substance on its
surface and being positioned downstream of the transfer zone for removing contaminants
from the image transfer member surface when being engaged in contact therewith. It
is also known that over time the tackiness of the cleaning member reduces and hence
the surface layer of the cleaning member needs to be rejuvenated. As disclosed in
US 4,705,388 (Huntjens et al. / Océ-Nederland BV) or EP 0994861 (Douvdevani et al.
/ Indigo N.V.), this may for instance be done by periodically developing a non-image
pattern of a tacky substance, in casu toner, on an image transfer member to rejuvenate
the surface layer of the cleaning member. In such rejuvenation state, the image transfer
member with the non-image toner pattern thereon passes the transfer zone while no
recording medium is supplied and without urging the counter member against the image
transfer member. Another example of such system is disclosed in US 6,226,489, where
cleaning substance is also applied to the image transfer member when the transfer
zone is opened. The non-image toner pattern on the image transfer member is guided
further towards the contact zone between the image transfer member and the cleaning
member, i.e. the cleaning zone. When the image transfer member with the non-image
toner pattern passes the cleaning zone, the non-image toner pattern is transferred
to the cleaning member surface thereby rejuvenating it. The periodic rejuvenation
of the tacky surface layer described is found to lead to inconsistent cleaning characteristics
caused by the reduction of the surface tackiness when proceeding in the operative
state towards the next rejuvenation period. From this perspective, it seems beneficial
to implement a high rejuvenation periodicity. However, as contrary to the operative
state, in the rejuvenation stage no prints or copies are generated, a high rejuvenation
periodicity is detrimental for the productivity of the image reproduction device.
These conflicting requirements demand for a new approach for rejuvenating the tacky
surface of the cleaning member.
[0004] Thus it is an object of the present invention to provide a device and method in which
an improved removal of contaminants from the surface of an image transfer member is
possible.
[0005] It is a further object of the present invention to rejuvenate the tacky surface of
the cleaning member substantially without affecting the productivity of the image
reproduction system.
[0006] It is still a further object of the present invention rejuvenating the tacky surface
of the cleaning member by providing refreshment material and simultaneously removing
any excess and/or contaminated tacky surface material therefrom.
[0007] To meet these objects according to a first aspect of the invention, there is provided
an image transfer device for transferring images of a marking substance to sheets
of a recording medium, the device comprising:
an endless image transfer member for receiving consecutive images of a marking substance
on its surface, the image transfer member being urged, in an operative state of the
transfer device, into contact with a counter member to form a transfer zone therebetween
for transferring the respective consecutive images to respective sheets of a recording
medium fed consecutively through the transfer zone; and
an endless cleaning member having, in an operative state of the transfer device, a
surface in contact with the surface of the image transfer member in a cleaning zone
downstream of the transfer zone, the surface of the cleaning member carrying a layer
of tacky substance;
characterised in that the device further comprises
a controllable applicator unit for providing, in an operative state of the image transfer
device, predetermined patterns of a cleaning substance to the surface of the image
transfer member in at least some non-image areas, the predetermined patterns of cleaning
substance on the image transfer member being substantially completely transferred
to the surface of the cleaning member in the cleaning zone. The present invention
is particularly relevant to printers and copiers where, to enable printing on a wide
variety of recording media, at least one image transfer device is provided to transfer
an image of marking substance from an image forming device to the recording medium.
The feature that non-image patterns of cleaning substance can be formed in the non-image
areas being the areas between consecutive images coinciding with the areas between
consecutive sheets is advantageous as it allows to rejuvenate the cleaning member
surface quasi continuously. Furthermore, as this takes place in the operative state,
i.e. while sheets of recording medium are fed through the transfer zone and hence
prints or copies of images are generated, this rejuvenation process does not negatively
affect the productivity of the printer or copier.
[0008] The cleaning member and the counter member may be selectively movable into and out
of contact with the image transfer member surface and may be independently driven.
Alternately, these items can be driven by the movement of the image transfer member.
[0009] The image transfer member may be in the form of a drum or a belt and may be heated.
In case the image transfer member is a belt a first and second backing roller may
be provided, the first backing roller cooperating with the cleaning member to form
the cleaning zone through which the belt passes, the second backing roller contacting
the back of the image transfer belt opposite the counter member such that in the transfer
zone both the belt and the recording medium pass while pressure is exerted on at least
one of the second backing roller and the counter member to define the contact.
[0010] The image transfer member typically has an outer layer of a silicone elastomer. The
counter member typically has an outer layer of a silicone elastomer, or a PTFE, or
a fluororubber. To ensure that substantially all the cleaning substance remains on
the image transfer member surface in the transfer zone where both members contact
each other, the outer layer of the counter member may be chosen such that it has a
lower affinity to the cleaning substance than the outer layer of the image transfer
member. When part of the cleaning substance transfers to the counter member surface,
a cleaning member with a tacky surface may also be engaged in contact with the counter
member. Alternately one can also opt to move the counter member out of contact with
the image transfer member in the time interval between two consecutive sheets in order
to ensure that the cleaning substance remains on the image transfer member surface
in the transfer zone. This is however less preferred as the disengagement and subsequent
engagement of the counter member after each sheet negatively influences reliability
and image quality, in particular image registering.
[0011] The cleaning member usually is a cleaning roller, although also a cleaning web may
be used. The cleaning roller is located downstream of the transfer zone and upstream
of any intermediate transfer zone where images of marking substance are transferred
to the image transfer member directly from an image forming member or indirectly via
one or more further image transfer members. The kind of marking substance and image
forming member which is used depends on the imaging technique used. Examples of imaging
techniques include ink jet, electrography including electrophotograpy, and magnetography.
Examples of marking substance include ink, dry particulate toner, and liquid toner.
For instance in case of electrophotography, the marking substance may be a dry particulate
toner, while the image forming member is a drum or a belt with a photoconductive outer
layer whereon a latent image is formed and subsequently developed with toner.
[0012] The tacky surface layer material and the cleaning substance can be formed of polymeric
material having good adhesive and adsorptive properties, especially at the operating
temperatures of the image transfer member. Preferably, the cleaning substance comprises
a polymer having a glass transition temperature below the temperature of the image
transfer member at the cleaning zone. Such polymeric material may be toner, as a toner
typically comprises a thermoplastic binder consisting of a thermoplastic resin or
mixture of resins including colouring matter, e.g. carbon black or colouring material
such as finely dispersed pigments or soluble dyes. The toner used as cleaning substance
may be one of the toners used as marking substance for rendering the images. Alternately,
it is also possible to use toner of a different composition as a cleaning substance,
for example containing a lower level of colouring material, or even no colouring material
at all.
[0013] The applicator unit may be a simple dosing unit, which is able to supply fresh cleaning
substance at a controllable rate and dose on predetermined locations of the moving
image transfer member according to a predetermined pattern. An example of such dosing
unit is a spray coating unit. Particular in case the cleaning substance is toner or
toner-like, the applicator unit may be an image forming unit. In the latter case a
predetermined pattern of cleaning substance is imaged directly on the image forming
member in some or each of the non-image areas. Alternately, a latent image pattern
is first formed on the image forming member and subsequently developed thereon. The
predetermined pattern of cleaning substance may be transferred in an intermediate
transfer zone to the image transfer member directly from an image forming member or
indirectly via one or more further intermediate image transfer members. Alternately,
the image forming member may constitute the image transfer member. The transferred
pattern of cleaning substance present on the image transfer member passes the transfer
zone. The remaining part of the pattern of cleaning substance present on the image
transfer member downstream of the transfer zone is transferred substantially completely
to the cleaning member in the cleaning zone.
[0014] In an embodiment of the invention, the cleaning member is a rotatable cleaning roller
having a surface with a plurality of spaced-apart perforations therein for discharging
any contaminants and excess cleaning substance assembled on the cleaning roller surface
into a cavity in the cleaning roller. For instance, the perforations may be in the
form of grooves. An advantage thereof is that building up on the cleaning member surface
of any excess tacky substance possibly mixed with contaminants is prevented. The cleaning
roller may be constructed of a metal such as steel or aluminium. The cleaning roller
may however also be made of other heat-resistant material to the extent comporting
with the operating temperature thereof. Such heat-resistant materials may include
heat-resistant plastics. Optionally a perforated conformable layer may be provided
on the cleaning member core material. In any case, the tacky layer is formed on the
cleaning member outer surface.
[0015] In a further embodiment of the invention, means are provided for synchronizing the
position of the perforations in the cleaning member and the predetermined patterns
of cleaning substance on the image transfer member to ensure that in the cleaning
zone cleaning substance is only present on the image transfer member surface outside
the perforations. The means for synchronizing the position may include a position
sensor for determining the axial position of the cleaning member.
[0016] In yet a further embodiment, the patterns of cleaning substance on the image transfer
member are such that the portions of the image transfer member surface, covered by
the patterns of cleaning substance, have an area coverage in the range from 1% to
30%. It is observed that by lowering the area coverage of the exposed portions, the
transfer efficiency of cleaning substance to the counter member surface in the transfer
zone can be effectively reduced.
[0017] According to a second aspect of the invention, there is provided a method of removing
contaminants from the surface of an endless image transfer member of a transfer device
in which in operation the endless image transfer member is urged into contact with
a counter member to form a transfer zone therebetween through which consecutive sheets
of a recording medium are fed, the method comprising:
contacting the image transfer member surface at a cleaning zone with an endless cleaning
member having a tacky surface layer of cleaning substance, thereby to transfer contaminants
from the image transfer member to the tacky surface; and
receiving consecutive images of a marking substance on the image transfer member and
transferring the respective consecutive images in the transfer zone to the respective
consecutive sheets;
characterised in that the method further comprises receiving patterns of a cleaning
substance on the image transfer member in at least some non-image areas, between at
least some of the consecutive images, the non-image areas being the areas between
consecutive images coinciding with the areas between consecutive sheets, the non-image
patterns of cleaning substance being substantially completely transferred to the surface
of the cleaning member in the cleaning zone.
BRIEF DESCRIPTION OF THE DRAWINGS
[0018]
Figure 1 is a schematic illustration of a printer according to an embodiment of the
present invention.
DETAILED DESCRIPTION OF THE INVENTION
[0019] In relation to the appended drawings, the present invention is described in detail
in the sequel. Several embodiments are disclosed. It is apparent however that a person
skilled in the art can imagine several other equivalent embodiments or other ways
of executing the present invention, the scope of the present invention being limited
only by the terms of the appended claims.
[0020] A printing system capable of printing on sheets of a recording medium is depicted
in Fig. 1. The printing system comprises an image transfer member, which can be moved
cyclically. The image transfer member is an endless member, such as e.g. a drum or
a belt. In this case the image transfer member is a cylindrical drum (1), which can
be moved in the direction of arrow (3). The image transfer member is constructed of
a metal sleeve, e.g. aluminium, with an elastomeric covering (2). Optionally, the
image transfer member may be provided with an outer layer of silicone rubber, e.g.
by means of coating. One or more process colours are available on the printing system
dependent whether it concerns a monochrome or a multi-colour printing system. For
each process colour, an image forming unit (4)(5)(6) is disposed along the path of
rotation of the intermediate transfer member. Each of these image forming units comprises
a cylindrical image forming member (7) on which a colour separation image of the corresponding
process is formed. In an operative state, the image forming members are all in pressure
contact with the image transfer member, the force with which the image forming members
are pressed against the image transfer member being at maximum 1000 N per linear meter,
e.g. 250 N per linear meter.
Each image forming member is formed of a metal drum with a photo-conductive outer
layer thereon, the various image forming devices being positioned along the circumference
of the image forming member. These image forming devices comprise a charging device
(11), e.g. a corona device, an exposing device (12), e.g. a LED array, for image-wise
exposure of the photo-conductive surface to thereby form a latent charge image thereon,
a development device (13) for developing the latent image with marking substance,
a cleaning device (14) for removing any residual marking substance present on the
image forming member after transfer of the developed separation image to the image
transfer member. The development device is in this case a magnetic brush development
device which comprises a magnetic roller (17) consisting of a rotatable sleeve with
a stationary magnet system therein. The magnetic roller is positioned along the circumference
of the image forming member with its surface at short distance from the image forming
member surface without contacting it. A reservoir (18) with electrically conductive
magnetically attractable dry particulate toner is positioned near the surface of each
of the magnetic rollers (17). Each reservoir contains toner in one of the process
colours. A stripper (19) is provided at each reservoir to ensure that an even layer
of particulate toner is applied to the sleeve of the magnetic roller.
[0021] Also disposed along the path of rotation of the image transfer member (1) is a rotatable
counter roller (23) which is selectively movable towards and away from the image transfer
member surface with controlled pressure. Means (not shown) are provided to drive this
counter member. When pressing the counter member against the image transfer member
surface a transfer zone is defined through which in operation sheets of recording
medium are passed using feed means and sheet discharging means. This feed means consists
of co-operating conveyor rollers (21) and a guide plate (22). The sheet discharging
means includes co-operating conveyor belts (24) (25).
[0022] Further disposed along the path of rotation of the image transfer member (1) downstream
of the transfer zone is a rotatable cleaning roller having a tacky surface. The cleaning
roller (30) may be driven by drive means (not shown) and is selectively movable into
and out-of an operative position in which the cleaning member surface is in contact
with the image transfer member surface. A helical perforation is formed in the cleaning
roller surface and extends to a cavity within the roller for discharging any contaminants
and /or excess cleaning substance assembled on the roller surface therein. This helical
perforation defines in the axial direction an alternating pattern of grooves and non-perforated
areas, referred to as dams. Although these parameters are not that critical, the width
and pitch of the perforation is of importance as they determine the ratio between
the cleaning area and the non-cleaning area of the roller. As cleaning is only performed
in the dam area and not in the grooves, proper consideration should be given when
determining these parameters. A large cleaning area is desirable but account should
be taken of the fact that the contaminants and/or excess cleaning substance assembled
on the cleaning roller surface dams must be able to reach the grooves. Hence, for
instance the viscosity of the cleaning substance should be involved in this consideration.
A position sensor (not shown) is provided to detect the axial position and optionally
also the radial position of the cleaning roller as well as control means (also not
shown) for controlling the position of the cleaning roller responsive to the detected
position.
[0023] The tackiness of the surface layer of the cleaning roller may be improved and the
viscosity of the layer may be adjusted by heating the surface layer upstream of the
cleaning zone. To enable this, a heating device may be provided for heating the cleaning
substance on the cleaning roller surface to render the surface tacky prior to contact
thereof with the transfer member surface. The heating device may be in the form of
a lamp located in the inner core of the roller. Alternatively, especially when the
cleaning roller has a conformable surface, external heating is preferred, for example
by use of an external radiant heat source. Ideally, means are provided for controlling
the heating of the toner particles, for example by the use of a heat sensor to sense
the temperature of the cleaning member surface, this sensor being coupled to a control
device for the heating device. Heating the toner particles on the cleaning roller
surface has several benefits. The heating device can be energized selectively to control
the temperature and tackiness of the cleaning roller surface. This is especially beneficial
at start up where, in the absence of such a heating device, it would take a significant
amount of time (and possibly wastage of receiving material) before the temperature
equilibria would be reached.
[0024] In operation, in order to reproduce an image a sequence of printing signals is generated.
Responsive to this sequence of printing signals the printing system sequentially forms
the respective separation images of marking substance of the corresponding process
colour on the respective image forming members (7). In the respective pressure contact
zones, the respective separation images are sequentially transferred in register to
the image transfer member to thereby form a registered multi-colour image thereon.
The marking substance is toner in dry particulate form. The registered multi-colour
toner image on the image transfer member is heated by means known per se so that the
toner softens and is rendered tacky. The printing system is such that the respective
separation images of marking particles are formed complementary. This means that marking
particles of a process colour are accumulated on the free surface of the image-carrying
member and substantially not on coloured marking particles already accumulated on
the image-carrying member. Substantially not means that any superimposed marking particles
of different process colours may not lead to visual deficiencies, i.e. visual with
the naked human eye, in the finally printed image.
The printing system subsequently transfers the registered multi-colour toner image
to a sheet of a recording medium which is controllably fed at the appropriate time
by the conveyor rollers (21) through the transfer zone defined by establishing pressure
contact between the rotating image transfer member and the rotating counter member.
The sheet carrying the printed image is subsequently discharged by the co-operating
conveyor belts (24) and (25). The image transfer member is further advanced towards
the cleaning zone where any contaminants present on its surface may be removed by
transferring them to the tacky surface of the rotating cleaning roller (30). When
printing consecutive images, e.g. a document of several pages and/or plural copies
of a single image or document, the printing job is defined such that the consecutive
images are printed each on separate sheets fed in consecution through the transfer
zone. Hence, for consecutive images both an inter-image area, being the area between
consecutive images carried on the image transfer member, can be defined as well as
an inter-sheet area, being the distance between the associated consecutive sheets.
The part of the inter-image area coinciding with the inter-sheet area is referred
to as the non-image area. According to the present invention a predetermined pattern
of cleaning substance is formed in the non-image area. This may be done by imaging
a predetermined pattern on the image forming member of one of the available process
colours and subsequently developing it thereon with the corresponding toner. The toner,
preferably black toner when available, used to form this predetermined pattern constitutes
the cleaning substance. The image forming unit and the formation process of the predetermined
pattern is controlled such that the transfer of the cleaning substance pattern to
the image transfer member in the pressure contact zone is effected in the non-image
area. When cleaning substance pattern in the non-image area reaches the transfer zone
in the interval between two consecutive sheets, it can not be transferred to a sheet
but instead will remain on the surface of the image transfer member or will be (partially)
transferred to the counter member surface (23). When the image transfer member is
moved further to the cleaning zone the cleaning substance pattern or at least the
residual part thereof will be transferred to the dams of the tacky cleaning roller
surface (30) thereby rejuvenating the tacky surface layer. To ensure that substantially
all cleaning substance is removed from the image transfer member surface in the cleaning
zone a pattern is selected which can be synchronised with the cleaning member using
the cleaning roller position detection and controlling means such that cleaning substance
is only present in the cleaning zone in the area coinciding with the dams of the cleaning
roller. For example, when the pitch of the helical perforation is 3.5 mm and the groove
width (dimension in axial direction) is 0.8 mm, typically a pattern is chosen having
a dam width of about 1.1 mm which is well within the dam width of the cleaning roller.
The dams of the pattern constitute the portions of the image transfer member surface
in the non-image area covered with cleaning substance, while the dam width of the
pattern is the width of the covered portions in the non-image area.
[0025] As stated before, when a cleaning substance pattern in a non-image area reaches the
transfer zone in the interval between two consecutive sheets, it will remain on the
surface of the image transfer member or will be (partially) transferred to the counter
member surface (23). To avoid that the cleaning substance transferred to the counter
member contaminates the back of subsequent sheets are transfers back to the image
transfer members surface, a tacky surface cleaning roller (35) may also be provided
to clean the counter member surface. Instead of providing the additional cleaning
roller or in combination therewith, one can also opt to take appropriate measures
to severely reduce or even nullify the transfer rate of cleaning substance to the
counter member surface. One or these measures could be the use of a counter member
surface layer having a lower affinity to cleaning substance compared to the image
transfer member surface layer. Examples of such counter member surface layers are
polyorganosiloxane layers, in particular the ones disclosed in EP0349072 (Schoustra
et al., Océ Technologies B.V.). Instead or in addition to this measure, on could also
opt to lower the area coverage of the portions of the image transfer member surface
in the non-image area covered by the patterns of cleaning substance as it has been
observed that this is beneficial to reduce the transfer rate of cleaning substance
to the counter member surface. For instance the area coverage may be chosen typically
in the range from 1% to 30%, or from 1% to 10%, or from 1% to 5%.
1. An image transfer device for transferring images of a marking substance to sheets
of a recording medium, the device comprising:
an endless image transfer member for receiving consecutive images of a marking substance
on its surface, the image transfer member being urged, in an operative state of the
transfer device, into moving contact with a counter member to form a transfer zone
therebetween for transferring the respective consecutive images to respective sheets
of a recording medium fed consecutively through the transfer zone;
an endless cleaning member having, in an operative state of the image transfer device,
a surface in moving contact with the surface of the image transfer member in a cleaning
zone downstream of the transfer zone, the surface of the cleaning member carrying
a layer of tacky substance; and
a controllable applicator unit for providing, in an operative state of the image transfer
device, predetermined patterns of a cleaning substance to the surface of the image
transfer member,
characterised in that, in an operative state of the image transfer device,
the predetermined patterns of cleaning substance are provided to the surface of the
image transfer member upstream to the transfer zone in at least some non-image areas,
being the areas between consecutive images coinciding with the areas between consecutive
sheets, the predetermined patterns of cleaning substance on the image transfer member
being guided through the transfer zone, while the image transfer member is urged against
the counter member, towards the cleaning zone where they are substantially completely
transferred to the surface of the cleaning member.
2. An image transfer device according to claim 1, wherein the cleaning member is a cleaning
roller having a surface with a plurality of spaced-apart perforations therein for
discharging any contaminants and excess cleaning substance assembled on the cleaning
roller surface.
3. An image transfer device according to claim 2, wherein the perforations are grooves.
4. An image transfer device according to claims 2 and 3, further comprising means for
synchronizing the position of the perforations and the predetermined patterns of cleaning
substance to ensure that in the cleaning zone cleaning substance is only present on
the image transfer member surface outside the perforations.
5. An image transfer device according to claim 4, wherein said means for synchronizing
the position include a position sensor for determining the axial position of the cleaning
member.
6. An image transfer device according to any preceding claim, wherein the portions of
the image transfer member surface, covered by the patterns of cleaning substance,
have an area coverage in the range from 1% to 30%.
7. An image transfer device according to any preceding claim, wherein the counter member
has an outer layer of a silicone elastomer, or a PTFE, or a fluororubber, and the
image transfer member has an outer layer of a silicone elastomer.
8. An image transfer device according any preceding claim, wherein the image transfer
member is in the form of a belt and the cleaning member cooperates with a backing
roller to form the cleaning zone through which the belt passes.
9. An image transfer device according to any preceding claim, wherein said cleaning substance
comprises a polymer having a glass transition temperature below the temperature of
the surface of the image transfer member at the cleaning zone.
10. A method of removing contaminants from the surface of an endless image transfer member
of an image transfer device in which in operation the endless image transfer member
is urged into contact with a counter member to form a transfer zone therebetween through
which consecutive sheets of a recording medium are fed, the method comprising:
contacting the image transfer member surface at a cleaning zone downstream the transfer
zone with an endless cleaning member having a tacky surface layer of cleaning substance,
thereby to transfer contaminants from the image transfer member to the tacky surface;
receiving consecutive images of a marking substance on the image transfer member;
and
receiving patterns of a cleaning substance on the image transfer member;
characterised in that the patterns of cleaning substance are received on the image transfer member in at
least some non-image areas, the non-image areas being the areas between the consecutive
images coinciding with the areas between consecutive sheets, the method further comprising
guiding the image transfer member via the transfer zone, where the respective consecutive
images are transferred to the respective consecutive sheets, to the cleaning zone
where the non-image patterns of cleaning substance are substantially completely transferred
to the surface of the cleaning member.