FIELD OF THE INVENTION
[0001] The invention relates in general to electrostatographic reproduction apparatus, and
more particularly to an improved magnetic brush development apparatus for an electrostatographic
reproduction apparatus.
DESCRIPTION OF THE PRIOR ART
[0002] Magnetic brush development apparatus for applying developer material to a latent
image in an electrostatographic reproduction apparatus are well known in the art.
Such apparatus may include a housing having a sump portion which contains a supply
of developer material. When the developer material comprises a mixture of magnetic
carrier particles and smaller pigmented marking particles, the material in the sump
is agitated to triboelectrically charge the material prior to delivering it to a magnetic
brush where it can be brought into association with, and transferred to, an electrostatic
latent image to develop such image.
[0003] U.S.-A-4,671,207 discloses a magnetic brush development apparatus particularly suitable
for use with developer material having pigmented marking particles and permanent magnetic
carrier particles. More particularly, the disclosed apparatus include a ribbon blender
that is used for agitating (mixing), feeding and triboelectrically charging such material
in the sump portion of a magnetic brush development apparatus, and a feed mechanism
that delivers material from the sump portion to a magnetic brush. The material delivered
to the magnetic brush is applied to the latent electrostatic image in a development
zone to develop the image. The ribbon blender is constructed to provide uniform flow
distribution of developer material across the length of the apparatus so that a sufficient
supply of material is delivered to the magnetic brush over its full extent to uniformly
develop the entire latent electrostatic image. A take-off skive, in contact with the
magnetic brush downstream of the development zone, strips excess developer material
from the magnetic brush and returns such material to the sump portion.
[0004] Since the pigmented marking particles are used during image development, replenishment
of the developer material must be periodically effected. Typical replenishment devices
include a reservoir for replenishment material with a flow communication path between
the reservoir and the sump of the of the development apparatus. A selectively actuable
member, such as a roller, controls flow of replenishment material through the path.
It has been found that under certain conditions the set up latitude between the replenishment
roller and the flow communication path is unduly limited which can result in inconsistent
replenishment or marking particle level sensor inconsistencies. Further, under certain
conditions measurement of level of replenishment material in the reservoir is inconsistent,
which can result in running out of replenishment material without knowing it.
[0005] It has also been found that under certain conditions the mounting of the take-off
skive imposes a force on the magnetic brush which causes excessive torque in the rotation
of the magnetic brush. Such excessive torque causes heat build up and accelerated
wear of the skive and the magnetic brush, and induces production of development material
flakes between the skive and the magnetic brush. These flakes result in undesirable
artifacts being produced in the developed image.
[0006] It has also been found that under certain conditions the mixing of replenished pigmented
marking particles and developer material does not completely occur. That is, the marking
particles do not charge sufficiently to disperse and adhere to the carrier particles
in the developer material in the sump of the development apparatus. This may result
in the generation of unacceptable artifacts in the developed image.
[0007] It has also been found that under certain conditions particulate material in an uncharged,
or low charged state, becomes airborne. Such airborne material can cause undesirable
artifacts in the developed images and/or exit from the development apparatus to contaminate
the interior of the electrostatographic reproduction machine.
SUMMARY OF THE INVENTION
[0008] It is an object of the present invention to provide a magnetic brush development
apparatus for applying developer material to a latent image on a moving image carrying
member to overcome the above-described deficiencies. According to the present invention
a magnetic brush development apparatus is provided as defined in Claim 1. Essentially,
the development apparatus includes a housing having a portion defining a sump adapted
to contain a supply of developer material, and a magnetic brush located substantially
within the housing in spaced relation to the sump portion for applying developer material
to the latent image. A feed mechanism including a metering assembly located within
the housing between the sump portion and the magnetic brush transports developer material
from the sump to the magnetic brush, and a mechanism located in the sump portion agitates
developer material and transports developer material to the feed mechanism. A take-off
skive for stripping development material from the magnetic brush after application
to a latent image and directing such material to the sump portion is mounted so that
the skive is self-adjustably sup- ported between the metering assembly and the magnetic
brush. In order to enhance the mixing of developer material, flow of developer material
is directed from the wall of the housing adjacent to the sump portion back into the
agitating and transport mechanism. Further, developer material in the sump portion
is replenished by a device which includes a reservoir for replenishment material adjacent
to the sump por- tion, a flow communication path between the reservoir and the sump
portion and a selectively rotatable roller located relative to the path to control
flow of replenishment material through the path. The entrance to the path is configured
to engage the roller such that the set up latitude between the roller and path is
increased. Measuring the level of replenishment material in the reservoir is facilitated
by the material monitor located in the bottom of the reservoir immediately upstream
of the flow communication path, the surface of the monitor being periodically swept
to assure accurate measurement of replenishment material level. Still further, a shield
is located upstream of the development zone between the housing and the image carrying
member for containing developer material within the development zone to substantially
prevent escape of airborne particulate material from the apparatus.
[0009] The invention, and its objects and advantages, will become more apparent in the detailed
description of the preferred embodiment presented below.
BRIEF DESCRIPTION OF THE DRAWINGS
[0010] In the detailed description of the preferred embodiment of the invention presented
below, reference is made to the accompanying drawings, in which:
Figure 1 is an end elevational view, partly in cross-section, of the improved magnetic
brush development apparatus according to the present invention;
Figure 2 is a side elevational view, on an enlarged scale, of a portion of the replenishment
skive wall of the magnetic brush development appara- tus shown in Fig. 1;
Figure 3 is an end elevational view, on an enlarged scale, of the take-off skive mounting
device for the magnetic brush development apparatus shown in Fig. 1; and
Figure 4 is a top plan view of a portion of the take-off skive mounting device for
the magnetic brush development apparatus shown in Fig. 1.
DETAILED DESCRIPTION OF THE INVENTION
[0011] Referring now to the accompanying drawings, Fig. 1 shows an improved magnetic brush
development apparatus according to this invention, generally designated by the numeral
10. The apparatus 10 is adapted to provide a supply of developer material, including
pigmented marking particles and carrier particles, to an electrostatic latent image
carried by a member 12 in order to develop the latent image on the member with the
marking particles. The member 12, which is for example part of an electrostato- graphic
reproduction apparatus, is in the form of an endless web or a drum, or can be discrete
sheets on which a reproduction is formed. The member 12 is moved past apparatus 10
in the direction shown by the arrow A during development of the latent image on the
member.
[0012] Apparatus 10 comprises a housing 14 having spaced, generally parallel, substantially
vertical side walls 16, 18; a generally semi-cylindrical bottom wall 20 that joins
the side walls; and end walls (not shown). The lower portion of the housing defines
a sump S for containing a supply of developer material. The developer material can
be of any known type, for example including two-component developer material comprising
hard, permanent magnetic carrier particles and pigmented marking particles, such as
disclosed in U.S.-A-4,546,060.
[0013] Developer material in sump S is agitated in order to mix the marking particles and
carrier particles, provide triboelectric charging of the developer material, move
the material along the length of the sump, and deliver developer material to a feed
mechanism 60. Such agitation is effected by a ribbon blender generally designated
by the numeral 26, such as disclosed in the aforementioned U.S.-A- 4,671,207. The
ribbon blender 26 comprises an outer helical ribbon 28 and an inner helical ribbon
30. Both ribbons are coiled concentrically about a shaft 32. Shaft 32 is, in turn,
concentrically located with respect to the semi-cylindrical bottom wall 20 of the
housing 14, and runs for substantially the full length thereof. The ribbons 28, 30
rotate with the shaft 32. Ribbon 28 may have the same pitch throughout its length,
or may have one pitch over half its length and the opposite pitch over the other half
of its length. The pitch orientation of ribbon 30 is selected to be opposite to the
pitch orientation of ribbon 28. When the shaft 32 is rotated in a counterclockwise
direction as viewed in Fig. 1, the ribbons move developer material in sump S in a
counterclockwise direction, as well as a direction from the front of the housing 14
toward the rear, and then from the rear of the housing toward the front. This results
in significant agitation and shearing of the developer material in order to triboelectrically
charge the material.
[0014] Under certain conditions, such as when fresh marking particles are added to the developer
material in the sump S in the manner described below, the marking particles may not
adequately mix with the carrier particles before delivery to the feed mechanism 60.
As a result of inadequate mixing, marking particles may be left uncharged or may only
be charged to a low level insufficient to function in the desired manner during development
of the latent electrostatic image on the member 12. This may result in formation of
airborne marking particles which can escape from the development station, and artifacts
in a finished reproduction due to incomplete development. In order to enhance mixing,
a protuberance 16a is formed on the wall 16 of the development station housing 14
adjacent to the ribbon blender 26 upstream of the feed mechanism 60. The protuberance
16a, which runs substantially the full length of the housing 14, directs flow of developer
material (particularly any replenished marking particles) from the wall of the housing
adjacent to the sump portion back into the ribbon blender thereby creating turbulence
in the developer material being agitated by the ribbon blender to effectively extend
the mixing path for the material. This gives the marking particles more time to disperse
within the developer material and adequately charge before being picked up and fed
by the mechanism 60 to the magnetic brush 36. Accordingly, the amount of uncharged
(or low charged) marking particles is substantially reduced thereby concomitantly
reducing undesirable airborne marking particles.
[0015] A magnetic brush, generally designated by the numeral 36, is located at the top of
housing 14. The magnetic brush 36 may be of any suitable construction, such as illustrated
for example in Fig. 1, where the magnetic brush includes a shell 38 of a non-magnetic
material that rotates counterclockwise as indicated by arrow 40 about a core 42. Core
42 comprises a plurality of permanent magnets rotatable in a clockwise direction as
shown by arrow 46. The axis of rotation of the core, coincident with the axis of rotation
of the shell, is designated generally by the numeral 48. A portion of the magnetic
brush 36 projects through the top of the housing 14 and lies directly underneath the
electrostatic latent image carrying member 12.
[0016] Immediately beneath the magnetic brush 36 is a feed mechanism generally designated
by the numeral 60. The feed mechanism 60 includes a metering assem- bly 50 having
a plate defining an elongated feed slot 54 that extends substantially the full length
of the magnetic brush and lies adjacent to the outer surface of the magnetic brush
shell 38. Developer material received from the lower portion of the housing 14 passes
through slot 54 to the brush 36, such material being attracted to the outer surface
of shell 38 by the magnets in the core 42 of the magnetic brush. A transport assembly
60a for the feed mechanism 60 is located between metering assembly 50 and the ribbon
blender 26. The transport assembly 60a receives developer material from the sump S
and the ribbon blender 26, and transports such material to the metering assembly 50
and through the slot 54 to the magnetic brush 36. The transport assembly 60a com-
prises, for example, a shell rotatable in a counterclockwise direction shown by the
arrow with a plurality of stationary magnets that extend counterclockwise from a position
generally directly above the ribbon blender 26 to a position just ahead of the feed
slot 54 (approximately 160 degrees). Developer material from the sump is attracted
to the shell and held to the shell in the area under the influence of the magnets.
Thus the material can be transported from the sump to the slot 54 without dropping
from the shell.
[0017] In operation, developer material provided to the magnetic brush 36 is carried by
the shell 38 into operative contact with the latent image carrying member 12 for developing
an electrostatic latent image on the image bearing member with pigmented marking particles
in a development zone between the brush and the member. Even with the improved developer
material mixing described above, some percentage of the marking particles are not
charged (or have low charge) and become airborne. As noted, these particles can cause
image artifacts or may exit the development apparatus 10 to cause contamination within
the reproduction apparatus or its environment. In order to substantially prevent escape
of the airborne marking particles from the development apparatus 10, a contamination
control flap 44 is provided. The flap 44 is a thin flexible member fixed to the housing
14 upstream of the development zone. The connection of the flap 44 to the housing
14 is effected such that the flap extends into the path of the latent image carrying
member 12, and is oriented at an angle with respect to the member to effect engagement
of the flap with the member under a minimal engagement force. In this manner damage
to the member 12 or undue wear of the flap 44 is minimized. The flap 44 then serves
as a seal between the development apparatus 10 and the member 12. Accordingly, any
airborne marking particles are trapped and forced into the developer nap of the development
zone. In such zone, the marking particles are charged and become part of the developed
image, or are returned with the excess developer material exiting the development
zone. In this manner, escape of the airborne marking particles is substantially prevented
and build up of uncharged marking particle within the development apparatus 10 is
greatly reduced.
[0018] After development of the latent image with marking particles by the magnetic brush
36, continued rotation of the shell 38 of the magnetic brush brings the developer
material remaining on the shell to a take-off skive 74 for scraping the material from
the shell. The removed material returns by gravity to the sump S where it is remixed
by the ribbon blender 26 with developer material remaining in the sump. The take-off
skive 74 includes an elongated blade 76 for removing developer material passing through
the development zone, from the shell 38. The blade 76 is attached to mounting members
78 (one shown in the drawings). As best shown in Figs. 3 and 4, the mounting members
78 define slots 78a which are adapted to receive pins 80 respectively extending from
end blocks 82 supporting the magnetic brush 36 whereby the take-off skive is capable
of limited self-adjusting movement. The slots 78a are oriented so that the limited
movement of the take-off skive 74, for any particular development apparatus, automatically
defines a position for the skive determined by the plate of the metering assembly
50 (engaged by the members 78) and the contour of the shell 38 (engaged by the blade
76). In operation, the blade 76 is held in contact with the shell 38 by developer
material scraped off of the shell. That is, the field of the magnets of the core 42
act to attract the developer material on the blade pulling the blade into intimate
contact with the shell. By utilizing the magnetic properties of the developer material
and the slotted mounting of the take-off skive to properly position the skive blade
76 against the shell 38, a lower torque is established for the magnetic brush 36 than
with prior take-off skive mounting arrangements employing positive forces for blade/shell
engagement. The lower torque is particularly significant in that it serves several
purposes. It reduces heat generated by the development apparatus, wear to the blade
of the skive, and the amount of flakes produced between the blade and the shell.
[0019] Since material returned from the magnetic brush 36 will be partially depleted of
marking particles (used up in the development of electrostatic latent images), fresh
marking particles must be periodically provided to the sump S to replenish the developer
material. To this end, a replenishment system 70 is located at one side of the housing
14 adjacent to the side wall 18. The replenishment system 70 includes a reservoir
72 for storing a supply of marking particle replenishment material. The common wall
18 defines an opening 18a which provides a flow communication path between the marking
particle reservoir 72 and the sump S. A fibrous replenishment brush 90 is rotatably
mounted in the bottom of the reservoir 72 adjacent to the opening 18a, the fibers
of the brush extending through the opening. The replenishment brush 90, when not rotating
acts to seal the opening to prevent marking particles from flowing from the reservoir
to the sump. However, when the concentration of marking particles in the developer
material in the sump (as determined by any well known concentration monitor for example
shown in Fig. 1 as mechanism 92) falls below a desired level for adequate latent image
development, the replenishment brush 90 is selectively rotated to feed a quantity
of fresh marking particles from the reservoir to the sump. The portion of the wall
18 forming the marginal edge 18b of the opening 18a has a saw-toothed configuration
(see Fig. 2). When the brush 90 is rotated in a counterclockwise direction, the saw-toothed
configuration acts to readily comb marking particles out of the fibers of the replenishment
brush. When compared to straight walls found in replenishment systems of prior development
apparatus, the saw-toothed configuration reduces the area in heavy contact with the
the brush fiber, concomitantly reducing the torque required to rotate the replenishment
brush. As a result of this torque reduction, the tolerance for locating the replenishment
brush 90 relative to the opening 18a is significantly expanded. This, in turn, broadens
the set up latitude for the replenishment brush under which acceptable replenishment
rates can be accomplished without producing unacceptably high torque levels.
[0020] The replenishment system 70 also includes an improved mechanism for sensing the level
of marking particles in the reservoir 72. The level sensing mechanism includes a sensor
94 mounted at the bottom of the replenishment system housing in a substan- tially
horizontal orientation. Such orientation is necessary to properly provide an "out
of marking particles" signal where the marking particles are fed from the reservoir
near one side at the bottom as shown in Fig. 1 of the drawings. For the sensor 94
to function properly, a wiper 96 is attached to the the outboard end of a rotatable
marking particle agitator 98 within the reservoir. The length of the agitator 98 and
the size of the wiper 96 are selected such that the wiper sweeps marking particles
from the face of the sensor 94 toward the replenishment brush 90 as the agitator is
rotated in a counterclockwise direction. As the agitator 98 passes the sensor 94,
the marking particles back fill behind the wiper 96 to recover the sensor. When there
is not enough marking particles to fill in after passage of the agitator, the sensor
will detect that the "out of marking particles" condition exists and produce the appropriate
warning signal. In this manner, marking particle level sensing is consistently assured.
1. A magnetic brush development apparatus (10) for applying developer material to a latent
image on a moving image carrying member (12), said apparatus including
a housing (14) having a wall portion (20) defining a sump (S) adapted to contain
a supply of developer material;
a magnetic brush (36) located within said housing for applying developer material
to the latent image;
a feed mechanism (26, 60) including a metering assembly (50) located within said
housing between said sump portion and said magnetic brush (36);
a take-off skive (74) for stripping development material from said magnetic brush
(36) after application to a latent image and directing such material to said sump
portion;
means (16a) for directing a flow of developer material into the agitating (26)
and transporting (60) means of said feed mechanism;
means (44) located upstream of the development zone for forming a shield between
said housing and said image carrying member (12) to prevent escape of airborne particulate
material from the apparatus;
a developer material replenishment device (70) including a reservoir (72) for replenishment
material adjacent to said sump portion;
a flow communication path between said reservoir and said sump portion, means in
such path located for controlling flow of replenishment material; and
means for measuring the level of replenishment material in said reservoir (72),
characterized in that
said take-off skive (74) includes means for self-adjusting mounting of said skive
between said metering assembly and said magnetic brush.
2. The magnetic brush development apparatus of claim 1 characterized by said skive including
a scraper blade (76) and mounting members (78) attached at opposite ends of said scraper
blade; and said mounting means including support means (80, 82) fixed to said magnetic
brush for supporting said mounting members with limited relative movement between
said mounting members and said support means.
3. The magnetic brush development apparatus of claim 2 characterized by said support
means including pins (80) and said mounting members defining elongated slots (78a)
for receiving said pins respectively.
4. The magnetic brush development apparatus of claim 3 characterized by said slots defined
by said mounting members being oriented such that said scraper blade is held in contact
with said magnetic brush by magnetic attraction of development material scraped by
said blade from said magnetic brush.