Developer material coating apparatus having developer material removing unit

A developer material coating apparatus includes a support member feeding unit for feeding the support member to a developer material coating region while carrying the support member thereon, a developer material coating unit for triboelectrically charging the developer material and electrostatically supplying the charged developer material toward the support member feeding unit to coat the developer material on the surface of the support member in the developer material coating region, and a developer material removing unit for sucking and removing the developer material attached to said support member feeding means, except for the developer material attached to the surface of the support member. The developer material removing unit comprises an air nozzle for sucking the developer material attached to the support member feeding unit under a negative pressure, a trap case intercommunicating with the air nozzle for withdrawing the sucked developer material through the air nozzle, an air filter provided in the trap case for trapping the sucked developer material and a negative pressure producing unit intercommunicating with the trap case for producing a negative pressure in said air nozzle to produce an air flow in a predetermined direction.

BACKGROUND OF THE INVENTION 
This invention relates to a developer material coating apparatus for 
coating a support member such as a plain paper with granular developer 
material, and more particularly to a developer material coating apparatus 
having a developer material removing unit. 
There has been recently utilized a color copying machine in which a color 
image is formed on a support member such as plain paper using granular 
developer material and a microcapsule sheet. A color image forming process 
of this type of color copying machine is as follows. A developer sheet is 
beforehand formed by coating the developer material on the support member 
such as plain paper, and the microcapsule sheet is exposed through an 
original to light to form a latent image on the microcapsule sheet. The 
microcapsule sheet having the latent image thereon and the developer sheet 
comprising the support member coated with the developer material are fed 
to a pressure-developing unit while contacted with each other under 
pressure. In the pressure-developing unit, the microcapsule sheet and the 
developer sheet are subjected to a pressure-developing process to develop 
the latent image on the microcapsule sheet into a visible color image on 
the developer sheet. Thereafter, the developer sheet having the visible 
color image thereon is fed to a heat-fixing unit to thermally fix the 
visible color image on the developer sheet. The developer material is 
formed of , for example, acid clay, binder and so on, and thus the 
developer sheet may comprise the support member coated with the developer 
material formed of the acid clay, the binder and so on. 
As described above, this type of color copying machine requires a process 
for coating the developer material on the support member such as plain 
paper, and thus a coating apparatus therefor. As a coating apparatus, 
there has been conventionally used a coating apparatus in which the 
developer material on the support member is charged with 
triboelectrification and then is electrostatically coated on the support 
member. 
FIG. 1 shows a conventional coating apparatus for coating the developer 
material on the support member such as plain paper. This coating apparatus 
comprises, for example, a support member feeding unit for feeding the 
support member to a developer material coating region in which the support 
member is electrostatically coated with the developer material and then 
discharging the support member coated with the developer material to an 
outside of the coating apparatus, and a developer material coating unit 
for triboelectrically charging the developer material and 
electrostatically supplying the charged developer material to the support 
member which has been fed to the developer material coating region. 
The developer material coating unit comprises a tank for accommodating the 
developer material S therein, a carry roller 52 for carrying the developer 
material thereon and a supply roller 51 for triboelectrically charging the 
developer material in cooperation with the carry roller 52 and supplying 
the charged developer material to the carry roller 52. The carry roller 52 
is grounded as shown in FIG. 1. The carry roller 52 and the supply roller 
51 are rotatably contacted with each other at the peripheral surfaces 
thereof, and the developer material S is triboelectrically charged at a 
predetermined polarity (positively or negatively ) at the contacted 
surfaces of the rollers 51 and 52 through a friction between the surface 
of the carry roller 52 and the developer material S. The charged developer 
material S is attached to peripheral surface of the carry roller 52 and 
then is fed to the developer material coating region while carried on the 
carry roller. 
The support member feeding unit comprises a counter electrode roller 53, 
which is supplied with a voltage having the opposite polarity to that of 
the charged developer material from a D.C. power source, a pair of guide 
rollers 55 provided away from the counter roller 53 and a carry belt 54 
such as an endless belt for feeding the support member to the developer 
material coating region while carrying the support member P thereon and 
discharging the support member coated with the developer material 
(developer sheet) to the outside of the coating apparatus, the carry belt 
54 being suspended among the counter roller 53 and the guide rollers 55. 
In FIG. 1, since the developer material S is positively charged, the 
counter electrode roller 53 is supplied with a negative voltage. 
The support member P carried on the carry belt 54 is fed to the developer 
material coating region by the rotation of the counter roller 53 and the 
guide rollers 55. The positively-charged developer material S on the carry 
roller 52 is electrostatically attracted toward the counter electrode 
roller 53 due to an electric field which is caused between the counter 
roller 53 having a positive potential and the grounded carry roller 52. 
That is, particles of the positively-charged developer material S is 
electrostatically attracted (flight) toward the counter electrode roller 
53 in the developer material coating region where the counter roller 53 
and the carry roller 52 are confronted to each other, and attach to the 
support member P to form a developer material layer m on the support 
member P, that is, a developer sheet. 
In the conventional developer material coating apparatus thus constructed, 
the developer material S, which has been electrostatically attracted 
toward to the counter electrode roller, is liable to be attached to any 
portion of carry belt 54, for example, the surface thereof located between 
the neighboring support members which are successively fed to the carry 
roller. Further, if the carry belt 54 has a hole in the surface thereof 
and a damaged portion therein, then the developer material is also 
attached to the surface of the counter electrode roller 53 through the 
hole and so on. Still further, if the counter electrode roller 53 is so 
designed as to have a longer width than the carry belt 54, then the 
developer material S is also attached to the surface of the counter 
electrode roller 53 through the side portion of the carry belt 54. Once 
the developer material S is attached to the surfaces of the carry belt 24 
and the counter electrode roller 53, it is very difficult to remove the 
developer material S from the carry belt 24 and the counter electrode 
roller 53 because of nonconductivity of the developer material S. 
Accordingly, the developer material S is liable to be stacked on the 
surfaces of the carry belt 24 and the counter electrode roller 53. The 
stacking of the developer material S on the carry belt and the counter 
electrode roller 53 prevents a gap between the support member P and at 
least one of the carry belt and the counter electrode roller 53 from 
having a regular interval (that is, a gap interval between the counter 
electrode roller 53 and the support member is not constant over the 
surface of the support member P) and therefore the developer material S is 
not uniformly coated over the surface of the support member P. When the 
microcapsule sheet and the support member coated unevenly with the 
developer material on the surface thereof (that is, the support member 
coated with a developer material layer having an uneven thickness) are 
pressure-developed in the pressure-developing unit while contacted with 
each other, an image having uneven image density is obtained. 
SUMMARY OF THE INVENTION 
An object of this invention is to provide a developer material coating 
apparatus in which the developer material attached to the counter 
electrode roller and the carry roller is easily and suitably removed 
therefrom and the interval of a gap between the support member and at 
least one of the counter electrode roller and the carry belt is kept to be 
constant, so that the developer material is uniformly coated on the 
support member. 
To attain the above object, a developer material coating apparatus 
according to this invention, comprises support member feeding means for 
feeding the support member to the developer material coating region while 
carrying the support member thereon, developer material coating means for 
triboelectrically charging the developer material and electrostatically 
supplying the charged developer material toward the support member feeding 
means to coat the developer material on the surface of the support member 
in the developer material coating region, and developer material removing 
means having a suction port for sucking and removing the developer 
material attached to the support member feeding means, except for the 
developer material attached to the surface of the support member, the 
developer material removing means being disposed such that the suction 
port confronts the support member feeding means. 
The developer material removing means comprises an air nozzle having the 
suction port at one end thereof for sucking the developer material 
attached to the support member feeding means under a negative pressure, a 
trap base intercommunicating with said air nozzle for withdrawing the 
sucked developer material through the air nozzle, an air filter provided 
in the trap case for trapping the sucked developer material and a negative 
pressure producing unit intercommunicating with the trap case for 
producing a negative pressure in the air nozzle to produce an air flow in 
a predetermined direction.

DETAILED DESCRIPTION OF THE INVENTION 
The preferred embodiments of this invention will be described hereunder 
with reference to the accompanying drawings. 
FIG. 2 shows a color image forming apparatus M provided with the developer 
material coating apparatus of this invention. 
The color image forming apparatus M comprises an exposure unit 1 provided 
at an upper portion of the apparatus for exposing a microcapsule 
(photosensitive and pressure-sensitive) sheet 7 to light through an 
original 10 to form a latent image on the microcapsule sheet 7, and a 
casing C for accommodating the microcapsule sheet 7 which travels between 
a sheet supply roller 5 and a sheet take-up roller 6, the developer 
material coating apparatus 2 provided substantially at the center of the 
casing M for producing a developer sheet from a support member P and 
developer material, a pressure-developer unit 3 provided beside the 
coating apparatus 2 for performing a pressure-developing process and so 
on. 
In the pressure-developing unit 3, the microcapsule sheet 7 which has been 
exposed to the light from the original is contacted under pressure with 
the developer sheet formed in the coating apparatus 2, to thereby develop 
the latent image on the microcapsule sheet 7 into a visible image on the 
developer sheet. After this pressure-developing process, the developer 
sheet is separated from the microcapsule sheet and fed to a heat-fixing 
unit 4 to thermally fix the visible image on the developer sheet. 
The exposure unit 1 includes a halogen lamp 8 and a rotatable color 
separation filter unit 9 provided below the halogen lamp 8 for passing a 
light emitted from the halogen lamp 9 therethrough and separating the 
light onto three primary color components. Below the color separation 
filter unit 9, the original 10 is disposed on an original stand 11. 
Further, two pairs of first and second guide rollers 12 are provided 
beside both sides of the original stand 11 (beside the right and left 
sides of the original in the FIG. 2) and other guide rollers 12 are 
further provided downstream of the second guide rollers 12 along a sheet 
feed path. 
The microcapsule sheet 7 is drawn out of the sheet supply roll 5 and is fed 
through the first guide rollers 12 to the original stand 11 for an 
exposure process to form the latent image corresponding to an original 
image on the microcapsule sheet 7. The microcapsule sheet having the 
latent image thereon is further fed through the second guide rollers 12 
and the other guide rollers 12 to the pressure-developing unit 3. 
A stack of plural support members such as plain paper are accommodated in a 
cassette 18 for accommodating the support members. A topmost support 
member is picked up from the stack of the support members and fed through 
a pair of guide rollers 19 to the carry belt 24 of the developer material 
coating apparatus 2. The support member P carried on the carry belt 24 is 
fed to the developer material coating region so that the developer 
material is coated on the support member to form a developer sheet. The 
developer sheet which has been formed in the developer material coating 
apparatus 2 in a manner as described hereinafter is fed through a pair of 
guide rollers 13 to a gap between a pair of pressure rollers 14 of the 
pressure-developing unit 3 while superposed on the microcapsule sheet 7. 
The pressure development is conducted on these superposed sheets under a 
pressure of the pressure rollers 14. 
The microcapsule sheet 7 passed through the pressure-developing unit 3 is 
taken up by the sheet take-up roller 6. On the other hand, the developer 
sheet passed through the pressure-developing unit 3 is fed through a pair 
of guide rollers 15 to the heat-fixing unit 4, and the discharged through 
a pair of guide rollers 16 to an outside of the apparatus. 
FIG. 3 shows a first embodiment of the developer material coating apparatus 
of this invention. 
Like the developer material coating apparatus as shown in FIG. 1, the 
developer material coating apparatus of this embodiment includes a support 
member feeding unit and a developer material coating unit. The support 
member feeding unit comprises a counter electrode roller 22 for 
electrostatically attract the developer material S, a pair of guide 
rollers 40 and a carry belt 24 suspended among the counter electrode 
roller 22 and the guide rollers 40 for feeding the support member P to the 
developer material coating region while carrying the developer material S 
on the outer surface thereof. The developer material coating unit 
comprises a tank 25 for accommodating the granular developer material S 
therein and a carry roller 21 provided at a side portion of the tank 25 
for carrying thereon and feeding the developer material S to the developer 
material coating region. 
In the developer material coating apparatus of this embodiment, a blade 26 
for smoothing the developer material S carried on the carry roller 21 is 
provided at an upper side of the carry roller 21 in such a manner as to 
contact with the carry roller 21 and a removing blade 25a is provided at 
one side of a bottom plate of the tank 25 in such a manner as to be spaced 
at a predetermined interval away from carry roller 21. The carry roller 21 
is supplied with a negative voltage from a voltage source 27 to keep the 
carry roller 21 at a negative potential, while the counter electrode 
roller 22 is grounded. Further, both of the carry roller 21 and the 
counter electrode roller 22 are clockwisely rotated by a rotation 
mechanism such as a motor (not shown). 
The counter electrode roller 22 and the carry roller 1 are spaced at a 
predetermined interval in the developer material coating region, and the 
support member P, which is picked up from the cassette 18 and fed through 
the rollers 9 as shown in FIG. 2, is fed through the developer material 
coating region while contacted with the counter electrode roller 22 
through the carry belt 24. The granular developer material S in the tank 
25 is drawn in a gap between the blade 26 and the carry roller 21 by a 
clockwise rotation of the carry roller 21, and triboelectrically 
negatively charged with friction between the carry roller 21 and the 
developer material S. The negatively charged developer material S is 
carried on the carry roller 21 while smoothed by the blade 26, and fed to 
the developer material coating region. 
In the developer material coating apparatus according to this embodiment, 
an air conveyor serving as developer material removing means is further 
provided to the support member feeding unit. In this embodiment, the air 
conveyor 30 is provided at an inner space of the supports member feeding 
unit which is defined between the counter electrode roller 22, the guide 
rollers 40 and the inner surface of the carry belt 24. The air conveyor 30 
includes a suction nozzle 31 for sucking the developer material attached 
to the surface of the counter electrode roller 22 under negative pressure, 
a trap case 32 connected to the suction nozzle 31 for withdrawing the 
developer material S removed from the counter electrode roller 22 by the 
nozzle 31, a trap filter 33 for trapping the sucked developer material S, 
and a ventilating fan 34 for producing a negative pressure. The suction 
nozzle 31 is disposed near the upper portion of the counter electrode 
roller 22 in the inner space in such a manner as to confront the surface 
of the counter electrode roller 22. With the negative pressure produced by 
the ventilating fan 34, the developer material S attached to the counter 
electrode roller 22 is sucked through the suction nozzle 31 to the trap 
case 32, and withdrawn therein while trapped by the trap filter 33. 
The operation of the developer material coating apparatus thus constructed 
will be described hereunder. 
When the carry roller 21 is clockwisely rotated, the granular developer 
material S is drawn in the gap between the blade 26 and the surface of the 
carry roller 21, and tribelectrically charged due to the friction. The 
charged developer material S is carried on the carry roller 21 and then 
fed to the developer material coating region where the carry roller 21 
confronts the counter electrode roller 22. As the carry roller 21 is 
supplied with the negative voltage and the counter electrode roller 22 is 
grounded, an electric field occurs between the carry roller 21 and the 
counter electrode roller 22. The charged (in this case, the 
negatively-charged) developer material S carried on the carry roller 21 is 
electrostatically attracted toward the counter electrode roller 22 with 
the electric field and then coated on the support member P. In this case, 
the charged developer material S is also attached to any portion (for 
example, the surface) of the carry belt 24 located between the 
successively-supplied neighboring support members P to the developer 
material coating region, and then is attached to the surface of the 
counter electrode roller 22 through the carry belt 24. 
By the rotation of the counter electrode roller 22, the erroneously 
attached developer material to the counter electrode roller 22 is fed to a 
developer material removing region where the counter electrode roller 22 
and the suction nozzle 31 are confronted with each other. An air flow 
directing from the suction nozzle 31 to the trap case 32 occurs, that is, 
a negative pressure occurs within the suction nozzle 31 by the ventilating 
fan 34 provided at the rear side of the trap case 32. Accordingly, the 
developer material S attached to the counter electrode roller 22 is sucked 
from the surface of the counter electrode roller 22 into the suction 
nozzle 31 under the negative pressure, and then trapped in the trap case 
32 by the trap filter 33. 
FIG. 4 shows a second embodiment of the developer material coating 
apparatus as shown in FIG. 3. The elements having the same functions as 
those of the first embodiment are represented by the same reference 
numerals, and the description thereof is eliminated. 
The air conveyor of this embodiment comprises a blower 35 for blowing an 
air, a trap case 32 having a trap filter 33 therein, an air tube 37 having 
one end connected to the blower 35 and the other end connected to the trap 
case 32 provided at the other end thereof and a trap filter 33, and a 
nozzle tube 38 having an air nozzle 31 at one end thereof. The air tube 37 
is so designed as to be constricted at any position of the elongated side 
wall, for example, at the middle portion thereof, and the other end of the 
nozzle tube 38 is connected to the constricted portion of the air tube 37 
in such a manner as to project from the elongated side wall of the air 
tube. 
In the air conveyor thus constructed, an air flow produced by the blower 35 
is directed through the constricted portion to the trap case 32. In this 
case, the air flow is accelerated by the contracted portion of the air 
tube 37, and thus a pressure at the contracted portion is reduced. As a 
result, the air nozzle 31 has a negative pressure therein. Accordingly, 
the developer material S attached to the counter electrode roller 22 is 
fed to the developer material removing region by the rotated on the 
counter electrode roller 22, and sucked into the air nozzle 31 under the 
negative pressure. The sucked developer material S is directed to the trap 
case 32 along the air flow and trapped in the trap case 32. 
FIG. 5 shows a third embodiment of the developer material coating apparatus 
according to this invention. The elements having the same functions as 
those of the first embodiment are represented by the same reference 
numerals, and the description thereof is eliminate. 
In this embodiment, the air conveyor 30 as shown in FIG. 3 is disposed at a 
rear side of the support member feeding unit such that the air nozzle 31 
of the air conveyor 30 confronts an non-feeding region of the carry belt 
24 which is defined by a region between the pair of guide rollers 40. Like 
the first embodiment, the air nozzle 31 is connected to the trap case 32, 
and the ventilating fan 34 for producing the negative pressure is provided 
at the rear side of the trap case 32 (that is, at the opposite side to the 
air nozzle 31 with respect to the trap case 32). 
In this embodiment, the developer material S is attached to any portion 
(for example, the surface) of the carry belt 24 located between the 
neighboring support members P in the developer material coating region, 
and then is fed to the non-feeding region where the carry belt 24 
confronts the air nozzle 31. As the air flow directing to the trap case 32 
occurs within the air nozzle, the developer material S attached to the 
carry belt 24 is sucked through the air nozzle 31 to the trap case 32 
along the air flow, and trapped in the trap case 32. 
In this invention, each of the air conveyors of the first to third 
embodiments is individually used. However, the air conveyors may be used 
in combination. 
As described above, according to the developer material coating apparatus 
of this invention, the developer material S stacked on the carry roller 
and the surface of the counter electrode roller are easily and suitably 
removed therefrom to keep constant a gap interval between the support 
member P and at least one of the carry roller and the counter electrode 
roller 22, so that the developer material is uniformly coated over the 
surface of the support member. Accordingly, when the developer sheet 
coated with the developer material and the exposed microcapsule sheet is 
pressure-developed while contacted with each other under pressure, 
irregularity (ununiformity) in the image density of an obtained image can 
be completely prevented.