It is known to use vacuum cleaning in image forming devices such as printing machines or printers.
For example, in xerographic printing architectures it is known to use vacuum devices to clean residual toner from the surface of a photoreceptor drum. Also in xerographic printing architectures, it is known to use vacuum devices to clean web-fed paper paths to promote general cleanliness, thereby preventing image quality defects due to stray paper dust particles.
It also is known to use vacuum cleaning in ink jet printing architectures. For example, in solid ink jet printers the media or paper introduces particulate contamination into the image exchange engine (“IME”) where it can reach the apertures of the print heads, resulting in temporary, intermittent weak or missing (“IWM”) or permanent, chronic weak or missing (“CWM”) jet failures. Such IWM or CWM jet failures, in turn, reduce print quality and the mean number of copies between interventions (“MCBI”). Moreover, it is well known that particulate contamination can find its way into the small jetting orifices characteristic of ink jet printheads, and cause either temporary or permanent printhead failures.
Accordingly, it is known to use vacuum plenums to remove contaminating particles in ink jet printers, especially in the vicinity of the ink jet print heads.
Also, in solid ink printing architectures which use an intermediate image drum, it is known that vacuum cleaning of the image drum can remove such contaminants from the drum surface and from the entrained air boundary layer, thus reducing the contamination flux to the print head aperture plate.
Further, it has been shown that vacuum cleaning of the imaging drum just upstream of the print heads can remove these contaminants from the drum and the air boundary later, thus reducing the number of jet outages and increasing printer reliability.
However, there are substantial limitations with these existing methods to remove contaminating particles.
Thus, there is a need for the present invention.
In a first aspect of the invention, there is described an image forming device including an imaging drum and one or more marking material dispensers arranged for forming a disposed image on an included imaging drum surface, the imaging drum arranged to transfer the disposed image to a media at an image transfer site, the image forming device including plural particle removal devices comprising at least a first particle removal device and a second particle removal device, the first particle removal device including a first vacuum port positioned such that the imaging drum rotates a first angle from the image transfer site to the first vacuum port, the second particle removal device including a second vacuum port positioned such that the imaging drum rotates a second angle from the second vacuum port to the one or more marking material dispensers.
In a second aspect of the invention, there is described an image forming device including an imaging drum and one or more marking material dispensers arranged for forming a disposed image on an included imaging drum surface, the imaging drum arranged to transfer the disposed image to a media at an image transfer site, the image forming device including plural particle removal devices comprising at least a first particle removal device and a second particle removal device, the first particle removal device including a first elongated slot positioned such that the imaging drum rotates a first angle from the image transfer site to the first slot, the second particle removal device including a second elongated slot positioned such that the imaging drum rotates a second angle from the second slot to the one or more marking material dispensers.
In a third aspect of the invention, there is described a printer including an imaging drum and one or more marking material dispensers arranged for forming a disposed image on an included imaging drum surface, the imaging drum arranged to transfer the disposed image to a media at an image transfer site; the printer including a first particle removal device and a second particle removal device; the first particle removal device including a first elongated slot positioned such that the imaging drum rotates a first angle from the image transfer site to the first slot, the first slot positioned as close as possible to the image transfer site; the second particle removal device including a second elongated slot positioned such that the imaging drum rotates a second angle from the second slot to the one or more marking material dispensers, the second slot positioned as close as possible to the one or more marking material dispensers; the first and second slots having respective shapes and sizes that are substantially identical; each slot comprising a slot length extending generally parallel to an included imaging drum axial and a slot width; the slot width comprising a slot width outboard value at an included slot outboard end and a smaller slot width inboard value at an included slot inboard end; the slot width value being substantially constant from the slot inboard end to a slot width-transition point located a slot constant-width portion length from the slot inboard end towards the slot outboard end, the slot width value gradually increasing from the slot width-transition point to the slot outboard end; the first particle removal device coupled to a vacuum source and the second particle removal device coupled to a vacuum source; the first slot 160 positioned proximate to the imaging drum surface to provide a first air flow and the second slot positioned proximate to the imaging drum surface to provide a second air flow; where the marking material comprises ink.
Briefly, an image forming device includes marking material dispensers for disposing an image on an imaging drum surface. The image forming device further includes plural particle removal devices comprising first and second particle removal devices coupled to a vacuum source. The first particle removal device includes a first vacuum port positioned as close as possible to an included image transfer site. The second particle removal device includes a second vacuum port positioned as close as possible to the marking material dispensers. The first and second vacuum ports are positioned proximate to the imaging drum surface to provide respective first and second air flows.
Referring now to
In one embodiment, the marking dispenser 71 comprises an ink jet print head.
In one embodiment, the marking dispenser 72 comprises an ink jet print head.
For good understanding, the one or more marking material dispensers or ink jet print heads 71, 72 are generally depicted in
Referring still to
In one embodiment, the imaging drum 10 comprises an intermediate image drum.
Still referring to
In one embodiment, the image forming device 400 comprises an ink jet printer.
In
In one embodiment, the image transfer site 0 comprises a transfix site, and the depicted element 60 comprises a corresponding transfix roller.
As shown, the image disposing and transferring arrangement 300 includes plural particle removal devices, where the plural particle removal devices comprise at least a first particle removal device 100 and a second particle removal device 200.
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In one embodiment, the two (2) depicted vacuum sources 190 and 290 comprise a plurality of vacuum sources, thus at least two (2) vacuum sources.
In another embodiment, the two (2) depicted vacuum sources 190 and 290 comprise only one (1) vacuum source. For good understanding, in this latter embodiment the depicted vacuum sources 190 and 290 comprise the identical element or apparatus. Thus, in this embodiment, the terms “vacuum source 190” and “vacuum source 290” both refer to the same component, part or item.
Still referring to
With reference to the first particle removal device 100, in one embodiment the integral first vacuum port 120,160 is positioned as close as possible to the image transfer site 0, thereby minimizing the first angle 51.
Also as shown, in one embodiment the second particle removal device 200 is positioned just upstream of the one or more marking material dispensers or ink jet print heads 70. For good understanding, the “upstream” direction is opposite to the depicted rotational direction 19 of the imaging drum 10. The second particle removal device 200 is positioned such that the imaging drum rotates 10 a second angular amount or second angle 52 from the integral second vacuum port 220, 260 to the one or more marking material dispensers 70.
With reference to the second particle removal device 200, in one embodiment the integral second vacuum port 220, 260 is positioned as close as possible to the one or more marking material dispensers 70, thereby minimizing the second angle 52.
Referring still to
In one embodiment, the plural particle removal devices comprise exactly two (2) particle removal devices, namely, the depicted first and second particle removal devices 100 and 200. Hence, in this embodiment as an arbitrary point on the imaging drum surface 16 angularly transits, moves, travels or rotates about the imaging drum radial 11 in a circular path or trajectory fixed by the imaging drum radius 18 from the image transfer site 0 to the marking dispenser leading edge 79, the point encounters exactly and only two (2) particle removal devices, namely, the depicted first and second particle removal devices 100 and 200.
In another embodiment, the plural particle removal devices comprise more than two (2) particle removal devices. In this latter embodiment, the image disposing and transferring arrangement 300 comprises a plurality (“N”) of particle removal devices, where “N” is an integer greater than 2, such as 3, 4, 5, 6, 7, etc. Hence, in this latter embodiment as an arbitrary point on the imaging drum surface 16 angularly transits, moves, travels or rotates about the imaging drum radial 11 in a circular path or trajectory fixed by the imaging drum radius 18 from the image transfer site 0 to the marking dispenser leading edge 79, the point encounters more and greater than two (2) particle removal devices, namely, at least one and perhaps a plurality of particle removal devices separate and distinct from, and in addition to, the depicted first and second particle removal devices 100 and 200.
As shown in
In another embodiment, the one or more marking material dispensers 70 dispense a marking material that is other than and different from ink.
Referring now to
As shown, in one embodiment the arrangement 300 comprises the first and second particle removal devices 110 and 210, where the devices 110 and 210 themselves are substantially as shown in
Also as shown, in another embodiment the arrangement 300 comprises the first and second particle removal devices 150 and 250, where the devices 150 and 250 themselves are depicted in
Referring still to
As shown in
Still referring to
With reference to the slot width 140, in one embodiment the corresponding slot width 140 value is substantially constant or uniform from the first slot inboard end 121 to the first slot outboard end 129.
With further reference to the slot width 140, in one embodiment the corresponding slot width 140 value is substantially non-constant or non-uniform from the first slot inboard end 121 to the first slot outboard end 129.
For good understanding, in
Still referring to the first vacuum port 120, in another embodiment the first vacuum port 120 comprises a plurality of holes disposed along the first vacuum port length 130. In this latter embodiment, the first vacuum port 120 is substantially similar to the vacuum port 31 in the foregoing U.S. Pat. No. 6,070,026 to Alfred J. Clafflin, Jr. (“Clafflin”), which patent is incorporated by reference hereinabove. Referring to the Clafflin patent, his vacuum port 31 is described from col. 2, line 66 to col. 3, line 1 in the patent text and depicted in
In a first variation of the first vacuum port 120 “Clafflin-type” embodiment described immediately above, a plurality of holes with substantially circular shapes are disposed along the first vacuum port length 130.
In a second variation of the first vacuum port 120 Clafflin-type embodiment, a plurality of holes with substantially non-circular shapes are disposed along the first vacuum port length 130.
In a third variation of the first vacuum port 120 Clafflin-type embodiment, a plurality of holes with substantially uniform or similar shapes are disposed along the first vacuum port length 130.
In a fourth variation of the first vacuum port 120 Clafflin-type embodiment, a plurality of holes with substantially non-uniform or non-similar shapes are disposed along the first vacuum port length 130.
In a fifth variation of the first vacuum port 120 Clafflin-type embodiment, a plurality of holes with substantially uniform or similar sizes or dimensions are disposed along the first vacuum port length 130.
In a sixth variation of the first vacuum port 120 Clafflin-type embodiment, a plurality of holes with substantially non-uniform or non-similar sizes or dimensions are disposed along the first vacuum port length 130.
In a seventh variation of the first vacuum port 120 Clafflin-type embodiment, a plurality of holes are disposed at substantially uniform or constant intervals along the first vacuum port length 130.
In an eighth variation of the first vacuum port 120 Clafflin-type embodiment, a plurality of holes are disposed at substantially non-uniform or non-constant intervals along the first vacuum port length 130.
In a ninth variation of the first vacuum port 120 Clafflin-type embodiment, a plurality of holes are disposed along the first vacuum port length 130 to form a substantially uniform or constant pattern.
In a tenth variation of the first vacuum port 120 Clafflin-type embodiment, a plurality of holes are disposed along the first vacuum port length 130 to form a substantially non-uniform or non-constant pattern.
In an eleventh variation of the first vacuum port 120 Clafflin-type embodiment, a plurality of holes are disposed along the first vacuum port length 130 and across the first vacuum port width 140 to form a substantially uniform or constant pattern.
In a twelfth variation of the first vacuum port 120 Clafflin-type embodiment, a plurality of holes are disposed along the first vacuum port length 130 and across the first vacuum port width 140 to form a substantially non-uniform or non-constant pattern.
Still referring to
As shown in
With reference to the slot width 240, in one embodiment the corresponding slot width 240 value is substantially constant or uniform from the second slot inboard end 221 to the second slot outboard end 229.
With further reference to the slot width 240, in one embodiment the corresponding slot width 240 value is substantially non-constant or non-uniform from the second slot inboard end 221 to the second slot outboard end 229.
For good understanding, in
Still referring to the second vacuum port 220, in another embodiment the second vacuum port 220 comprises a plurality of holes disposed along the second vacuum port length 230. In this latter “Clafflin-type” embodiment the second vacuum port 220 thus is similar to the vacuum port 31 of the Clafflin patent as described above in connection with the first vacuum port 120.
In a first variation of the second vacuum port 220 “Clafflin-type” embodiment described immediately above, a plurality of holes with substantially circular shapes are disposed along the second vacuum port length 230.
In a second variation of the second vacuum port 220 Clafflin-type embodiment, a plurality of holes with substantially non-circular shapes are disposed along the second vacuum port length 230.
In a third variation of the second vacuum port 220 Clafflin-type embodiment, a plurality of holes with substantially uniform or similar shapes are disposed along the second vacuum port length 230.
In a fourth variation of the second vacuum port 220 Clafflin-type embodiment, a plurality of holes with substantially non-uniform or non-similar shapes are disposed along the second vacuum port length 230.
In a fifth variation of the second vacuum port 220 Clafflin-type embodiment, a plurality of holes with substantially uniform or similar sizes or dimensions are disposed along the second vacuum port length 230.
In a sixth variation of the second vacuum port 220 Clafflin-type embodiment, a plurality of holes with substantially non-uniform or non-similar sizes or dimensions are disposed along the second vacuum port length 230.
In a seventh variation of the second vacuum port 220 Clafflin-type embodiment, a plurality of holes are disposed at substantially uniform or constant intervals along the second vacuum port length 230.
In an eighth variation of the second vacuum port 220 Clafflin-type embodiment, a plurality of holes are disposed at substantially non-uniform or non-constant intervals along the second vacuum port length 230.
In a ninth variation of the second vacuum port 220 Clafflin-type embodiment, a plurality of holes are disposed along the second vacuum port length 230 to form a substantially uniform or constant pattern.
In a tenth variation of the second vacuum port 220 Clafflin-type embodiment, a plurality of holes are disposed along the second vacuum port length 230 to form a substantially non-uniform or non-constant pattern.
In an eleventh variation of the second vacuum port 220 Clafflin-type embodiment, a plurality of holes are disposed along the second vacuum port length 230 and across the second vacuum port width 240 to form a substantially uniform or constant pattern.
In a twelfth variation of the second vacuum port 220 Clafflin-type embodiment, a plurality of holes are disposed along the second vacuum port length 230 and across the second vacuum port width 240 to form a substantially non-uniform or non-constant pattern.
Now referring generally to the first and second particle removal devices 110 and 210, in one embodiment the integral first and second vacuum ports 120 and 220 include respective shapes and sizes that are substantially identical.
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In one embodiment, the second vacuum port 220 is positioned as close as possible to the marking dispenser leading edge 79, thereby minimizing the second angle 52.
Referring still to
The first particle removal device reference number 150 is shown inside parenthesis symbols in
As shown in
The first vacuum port 160 forms a first elongated slot 160 including an inboard end 161, an outboard end 169, with a slot length 170 extending generally parallel to the imaging drum axial 11. The first slot 160 further comprises a slot width 180.
In
Referring still to
The second vacuum port 260 forms a second elongated slot 260 including an inboard end 261, an outboard end 269, with a slot length 270 extending generally parallel to the imaging drum axial 11. The second slot 260 further comprises a slot width 280.
The foregoing reference numbers 260, 260′, 261, 269 and 270 are shown inside parenthesis symbols in
In one embodiment, the first and second vacuum ports 160 and 260 include respective shapes and sizes that are substantially identical.
Still referring to
In one embodiment, the first vacuum port 160 is positioned as close as possible to the image transfer site 0, thereby minimizing the first angle 51.
Referring still to
In one embodiment, the second vacuum port 260 is positioned as close as possible to the marking dispenser leading edge 79, thereby minimizing the second angle 52.
Referring now generally to the latter two drawing views
For good understanding, the first vacuum port 160 and the first slot 160 comprise the identical element or apparatus. Thus the terms “first vacuum port 160” and “first slot 160” both refer to the same component, part or item.
Likewise, the second vacuum port 260 and the second slot 260 comprise the identical element or apparatus. Thus the terms “second vacuum port 260” and “second slot 260” both refer to the same component, part or item.
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Referring to the first slot constant-width portion 171, as depicted, the first slot 160 is shaped such that the first slot width value 180 is substantially constant or uniform from the first slot inboard end 161 to a first slot width-transition point 175 located a first slot constant-width portion length (reference letter “W”) from the first slot inboard end 161 in the direction towards the first slot outboard end 169.
Referring now to the first slot tapered-width portion 179, as shown, the first slot 160 is shaped such that the first slot width value 180 gradually increases from the first slot width-transition point 175 to the first slot outboard end 169.
Referring still to the first slot 160, in one embodiment the first slot length value 170 is about 335 milli-Meters (“mm”), the first slot width 180 inboard value (X) at the first slot inboard end 161 is about 3.17 mm, the first slot width 180 outboard value (Y) at the first slot outboard end 169 is about 6.33 mm, and the first slot constant-width portion length value (W) is about 150 mm.
As further shown in
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In
Referring to the second slot constant-width portion 271, as depicted in
In
Referring now to the second slot tapered-width portion 279, as shown, the second slot 260 is shaped such that the second slot width value 280 gradually increases from the second slot width-transition point 275 to the second slot outboard end 269.
Referring still to the second slot 260, in one embodiment the second slot length value 270 is about 335 mm, the second slot width 280 inboard value (X) at the second slot inboard end 261 is about 3.17 mm, the second slot width 280 outboard value (Y) at the second slot outboard end 269, is about 6.33 mm, and the second slot constant-width portion length value (W) is about 150 mm.
In summary, plural particle removal devices 100 and 200 are arranged to vacuum clean the image drum 10. The plural particle removal devices 100 and 200 act to reduce or remove particle contaminates from the drum surface 16 and from the entrained air boundary layer, thus reducing the contamination flux to the print head aperture plate. In turn, the number of ink jet failures is reduced, thereby increasing reliability of the printer 400.
Further, in one embodiment, the plural particle removal devices form a dual-site particle abatement system. In one embodiment, the dual-site particle abatement system comprises plural vacuum plenums or manifolds with slit orifices are placed in close proximity to the drum 10. Sufficient vacuum is applied to the plural plenums such that a shear force is developed at the surface of the drum which is sufficient to dislodge contaminates adhering to the drum. Once dislodged, the contamination is captured by the plural vacuum air flows and redirected away from the printhead, where it is most likely to cause printhead failures. In addition to collecting contaminants adhered to the drum, the plural vacuum plenums also collect airborne contamination particles that are entrained in the boundary layer surrounding the drum.
Moreover, in one embodiment, the dual-site particle abatement system comprises plural vacuum plenums or manifolds, connecting ducts, and one or more blowers to generate the vacuum airflows. In one embodiment, this system cleans the intermediate image drum surface and the surrounding entrained air layer in a typical solid ink printing architecture.
Hence, the dual-site vacuum abatement concept as described herein is applied to ink jet technologies where the problem of dust contamination can be catastrophic, and is a major driver of print head reliability.
Referring generally to
As shown in
A new experimental technique was created to measure the number and size distribution of contaminant particles that migrate and accumulate on the print head aperture plate. This particle collection and analysis technique was used in solid ink printers to characterize the contaminant flux to the print head under control conditions (no abatement) and also with vacuum abatement operating at different levels of airflow. The results very clearly indicate that, given ample air flow such as, for example, from 5 to 8 cubic feet of air flow per minute (“cfm”), the use of vacuum abatement significantly reduces the contaminant flux to the front face of the printhead.
Furthermore, it has been proven that there is a direct correlation between the amount of particle contamination at the printhead and the printhead failure rate. Moreover, it has been proven that by controlling the particle contamination levels found at the printhead with vacuum abatement, print head reliability can be significantly improved.
In one embodiment, each particle removal device 100 and 200 in the dual-site particle abatement system uses an airflow (91 and 92) of 8 cfm, with a spacing between the drum surface 16 and the vacuum port orifice (41 and 42) of 0.040 inches.
In one embodiment, the abatement data for printers equipped with the dual-site particle abatement system indicates a 38 per-cent (%) reduction in IWM rate when compared to the control group without abatement.
Moreover, in one embodiment of the dual-site particle abatement system, the second particle removal device 200 is placed just upstream of the print heads 70 while the first particle removal device 100 is placed just downstream of the source of the paper particle contamination, that is, just downstream of the transfix site 0. The concept is to vacuum clean the paper dust just after it is introduced to the drum area. The goal is to capture most of the contamination before it has a chance to spread downstream on the drum or before it is thrown off either into the entrained boundary later or into the general environment of the print area. The second particle removal device 200 remains just upstream of the particle-sensitive print heads 70 and serves as a last line of defense for the nozzle faces.
In one embodiment, the dual-site particle abatement system is optimized for a specific location. For example, in one embodiment the first particle removal device 100 near the transfix site 0 utilizes a high-volume but moderate air pressure to engulf the paper particulate from a large area whereas the second particle removal device 200 near the printheads 70 is a low-volume, very low air pressure system that only pulls air locally near the printheads 70.
In another embodiment, types of abatement are mixed, for example, vacuum abatement at the transfix site 0 but sticky baffles that getter particles from the boundary layer in which the print head is immersed.
Thus, there has been described the first aspect of the invention, namely, an image forming device 400 including an imaging drum 10 and one or more marking material dispensers 70 arranged for forming a disposed image 2 on an included imaging drum surface 16, the imaging drum 10 arranged to transfer the disposed image 2 to a media or paper 5 at an image transfer site 0, the image forming device 400 including plural particle removal devices comprising at least a first particle removal device 100, 110, 150 and a second particle removal device 200, 210, 250, the first particle removal device 100 including a first vacuum port 120,160 positioned such that the imaging drum 10 rotates 19 a first angle 51 from the image transfer site 0 to the first vacuum port 120, 160, the second particle removal device 200 including a second vacuum port 220, 260 positioned such that the imaging drum 10 rotates 19 a second angle 52 from the second vacuum port 220, 260 to the one or more marking material dispensers 70.
The following forty-five (45) sentences A-S1 apply to the foregoing first aspect of the invention:
A. In one embodiment, the first vacuum port 120,160 is positioned as close as possible to the image transfer site 0, thereby minimizing the first angle 51.
B. In one embodiment, the second vacuum port 220, 260 is positioned as close as possible to the one or more marking material dispensers 70, thereby minimizing the second angle 52.
C. In one embodiment, the imaging drum 10 comprises a transfix drum.
D. In one embodiment, the one or more marking material dispensers 70 comprise one or more ink jet print heads.
E. In one embodiment, the first vacuum port 120 comprises a plurality of holes with substantially circular shapes disposed along an included first vacuum port length 130.
F. In one embodiment, the first vacuum port 120 comprises a plurality of holes with substantially non-circular shapes disposed along an included first vacuum port length 130.
G. In one embodiment, the first vacuum port 120 comprises a plurality of holes with substantially uniform or similar shapes disposed along an included first vacuum port length 130.
H. In one embodiment, the first vacuum port 120 comprises a plurality of holes with substantially non-uniform or non-similar shapes disposed along an included first vacuum port length 130.
I. In one embodiment, the first vacuum port 120 comprises a plurality of holes with substantially uniform or similar sizes or dimensions disposed along an included first vacuum port length 130.
J. In one embodiment, the first vacuum port 120 comprises a plurality of holes with substantially non-uniform or non-similar sizes or dimensions disposed along an included first vacuum port length 130.
K. In one embodiment, the first vacuum port 120 comprises a plurality of holes disposed at substantially uniform or constant intervals along an included first vacuum port length 130.
L. In one embodiment, the first vacuum port 120 comprises a plurality of holes disposed at substantially non-uniform or non-constant intervals along an included first vacuum port length 130.
M. In one embodiment, the first vacuum port 120 comprises a plurality of holes disposed along an included first vacuum port length 130 to form a substantially uniform or constant pattern.
N. In one embodiment, the first vacuum port 120 comprises a plurality of holes disposed along an included first vacuum port length 130 to form a substantially non-uniform or non-constant pattern.
O. In one embodiment, the first vacuum port 120 comprises a plurality of holes disposed along an included first vacuum port length 130 and across an included first vacuum port width 140 to form a substantially uniform or constant pattern.
P. In one embodiment, the first vacuum port 120 comprises a plurality of holes disposed along an included first vacuum port length 130 and across an included first vacuum port width 140 to form a substantially non-uniform or non-constant pattern.
Q. In one embodiment, the first vacuum port 120, 160 forms a first elongated slot 120, 160 comprising a first slot length 130, 170 extending generally parallel to an included imaging drum axial 11.
R. In one embodiment, the first slot 120 comprises a slot width 140 where the corresponding slot width 140 value is substantially constant or uniform from an included first slot inboard end 121 to an included first slot outboard end 129.
S. In one embodiment, the first slot 120 comprises a slot width 140 where the corresponding slot width 140 value is substantially non-constant or non-uniform from an included first slot inboard end 121 to an included first slot outboard end 129.
T. In one embodiment, the first slot 160 includes a first slot width 180, where the first slot width 180 comprises a first slot width outboard value at an included first slot outboard end 169 and an equal or smaller first slot width inboard value at an included first slot inboard end 161.
U. In one embodiment, the first slot width 180 value is substantially constant or uniform from the first slot inboard end 161 to a first slot width-transition point 175 located a first slot constant-width portion length from the first slot inboard end 161 towards the first slot outboard end 169, the first slot width 180 value gradually increasing from the first slot width-transition point 175 to the first slot outboard end 169.
V. In one embodiment, the first slot length 170 is about 335 mm, the first slot width 180 inboard value at the first slot inboard end 161 is about 3.17 mm, the first slot width 180 outboard value at the first slot outboard end 169 is about 6.33 mm, and the first slot constant-width portion length value is about 150 mm.
W. In one embodiment, the second vacuum port 220 comprises a plurality of holes with substantially circular shapes disposed along an included second vacuum port length 230.
X. In one embodiment, the second vacuum port 220 comprises a plurality of holes with substantially non-circular shapes disposed along an included second vacuum port length 230.
Y. In one embodiment, the second vacuum port 220 comprises a plurality of holes with substantially uniform or similar shapes disposed along an included second vacuum port length 230.
Z. In one embodiment, the second vacuum port 220 comprises a plurality of holes with substantially non-uniform or non-similar shapes disposed along an included second vacuum port length 230.
A1. In one embodiment, the second vacuum port 220 comprises a plurality of holes with substantially uniform or similar sizes or dimensions disposed along an included second vacuum port length 230.
B1. In one embodiment, the second vacuum port 220 comprises a plurality of holes with substantially non-uniform or non-similar sizes or dimensions disposed along an included second vacuum port length 230.
C1. In one embodiment, the second vacuum port 220 comprises a plurality of holes disposed at substantially uniform or constant intervals along an included second vacuum port length 230.
D1. In one embodiment, the second vacuum port 220 comprises a plurality of holes disposed at substantially non-uniform or non-constant intervals along an included second vacuum port length 230.
E1. In one embodiment, the second vacuum port 220 comprises a plurality of holes disposed along an included second vacuum port length 230 to form a substantially uniform or constant pattern.
F1. In one embodiment, the second vacuum port 220 comprises a plurality of holes disposed along an included second vacuum port length 230 to form a substantially non-uniform or non-constant pattern.
G1. In one embodiment, the second vacuum port 220 comprises a plurality of holes disposed along an included second vacuum port length 230 and across an included second vacuum port width 240 to form a substantially uniform or constant pattern.
H1. In one embodiment, the second vacuum port 220 comprises a plurality of holes disposed along an included second vacuum port length 230 and across an included second vacuum port width 240 to form a substantially non-uniform or non-constant pattern.
I1. In one embodiment, the second vacuum port 220, 260 forms a second elongated slot 220, 260 comprising a second slot length 230, 270 extending generally parallel to an included imaging drum axial 11.
J1. In one embodiment, the second slot 220 comprises a slot width 240 where the corresponding slot width 240 value is substantially constant or uniform from an included second slot inboard end 221 to an included second slot outboard end 229.
K1. In one embodiment, the second slot 220 comprises a slot width 240 where the corresponding slot width 240 value is substantially non-constant or non-uniform from an included second slot inboard end 221 to an included second slot outboard end 229.
L1. In one embodiment, the second slot 260 includes a second slot width 280, where the second slot width 280 comprises a second slot width outboard value at an included second slot outboard end 269 and an equal or smaller second slot width inboard value at an included second slot inboard end 261.
M1. In one embodiment, the second slot width 280 value is substantially constant or uniform from the second slot inboard end 261 to a second slot width-transition point 275 located a second slot constant-width portion length from the second slot inboard end 261 towards the second slot outboard end 269, the second slot width 280 value gradually increasing from the second slot width-transition point 275 to the second slot outboard end 269.
N1. In one embodiment, the second slot length 270 is about 335 mm, the second slot width 280 inboard value at the second slot inboard end 261 is about 3.17 mm, the second slot width 280 outboard value at the second slot outboard end 269 is about 6.33 mm, and the second slot constant-width portion length value is about 150 mm.
O1. In one embodiment, the first particle removal device 100, 110, 150 and the second particle removal device 200, 210, 250 are arranged to couple 101 and 201 to a vacuum source (namely, at least one vacuum source of vacuum source 190 and vacuum source 290); the first vacuum port 120, 160 thus providing a first air flow 91 and the second vacuum port 220, 260 thus providing a second air flow 92.
P1. In one embodiment, the plural particle removal devices comprises exactly two (2) particle removal devices 100 and 200.
Q1. In one embodiment, the image transfer site 0 comprises a transfix site.
R1. In one embodiment, the marking material comprises ink.
S1. In one embodiment, the image forming device 400 comprises a printing machine or printer.
Also, there has been described the second aspect of the invention, namely, an image forming device 400 including an imaging drum 10 and one or more marking material dispensers 70 arranged for forming a disposed image 2 on an included imaging drum surface 16, the imaging drum 10 arranged to transfer the disposed image 2 to a media or paper 5 at an image transfer site 0, the image forming device 400 including plural particle removal devices comprising at least a first particle removal device 110, 150 and a second particle removal device 210, 250, the first particle removal device 110, 150 including a first elongated slot 120, 160 positioned such that the imaging drum 10 rotates a first angle 51 from the image transfer site 0 to the first slot 120,160, the second particle removal device 210, 250 including a second elongated slot 220, 260 positioned such that the imaging drum 10 rotates a second angle 52, from the second slot 220, 260 to the one or more marking material dispensers 70.
The following eleven (11) sentences T1-D2 apply to the foregoing second aspect of the invention:
T1. In one embodiment, the first slot 120,160 is positioned as close as possible to the image transfer site 0, thereby minimizing the first angle 51; and the second slot 220, 260 is positioned as close as possible to the one or more marking material dispensers 70, thereby minimizing the second angle 52.
U1. In one embodiment, the imaging drum 10 comprises a transfix drum and the image transfer site 0 comprises a transfix site.
V1. In one embodiment, the first slot 160 forms a first slot length 170 and a first slot width 180, where the first slot width 180 comprises a first slot width outboard value at an included first slot outboard end 169 and an equal or smaller first slot width inboard value at an included first slot inboard end 161.
W1. In one embodiment, the first slot width 180 value is substantially constant or uniform from the first slot inboard end 161 to a first slot width-transition point 175 located a first slot constant-width portion length from the first slot inboard end 161 towards the first slot outboard end 169, the first slot value 180 value gradually increasing from the first slot width-transition point 175 to the first slot outboard end 169.
X1. In one embodiment, the first slot length 170 is about 335 mm; the first slot width 180 inboard value at the first slot inboard end 161 is about 3.17 mm; the first slot width 180 outboard value at the first slot outboard end 169 is about 6.33 mm; and the first slot constant-width portion length value is about 150 mm.
Y1. In one embodiment, the first slot 160 and the second slot 260 include respective shapes and dimensions that are substantially identical.
Z1. In one embodiment, the one or more marking material dispensers 70 comprise one or more ink jet print heads.
A2. In one embodiment, the plural particle removal devices exclusively comprise the first particle removal device 150 and the second particle removal device 250.
B2. In one embodiment, the first particle removal device 150 and the second particle removal device 250 are arranged to couple 101 and 201 to a vacuum source (namely, at least one vacuum source of vacuum source 190 and vacuum source 290) such that the first slot 160 provides a first air flow 91 and the second slot 260 provides a second air flow 92.
C2. In one embodiment, the marking material comprises ink.
D2. In one embodiment, the image forming device 400 comprises a printing machine or printer.
Further, there has been described the third aspect of the invention, namely, a printer 400 including an imaging drum 10 and one or more marking material dispensers 70 arranged for forming a disposed image 2 on an included imaging drum surface 16, the imaging drum 10 arranged to transfer the disposed image 2 to a media or paper 5 at an image transfer site 0; the printer 400 including a first particle removal device 150 and a second particle removal device 250; the first particle removal device 150 including a first elongated slot 160 positioned such that the imaging drum 10 rotates 19 a first angle 51 from the image transfer site 0 to the first slot 160, the first slot 160 positioned as close as possible to the image transfer site 0; the second particle removal device 250 including a second elongated slot 260 positioned such that the imaging drum 10 rotates 19 a second angle 52 from the second slot 260 to the one or more marking material dispensers 70, the second slot 260 positioned as close as possible to the one or more marking material dispensers 70; the first and second slots 160 and 260 having respective shapes and sizes that are substantially identical; each slot 160, 260 comprising a slot length 170, 270 extending generally parallel to an included imaging drum axial 11 and a slot width 180, 280; the slot width 180, 280 comprising a slot width outboard value at an included slot outboard end 169, 269 and a smaller slot width inboard value at an included slot inboard end 161, 261; the slot width value 180, 280 being substantially constant from the slot inboard end 161, 261 to a slot width-transition point 175, 275 located a slot constant-width portion length from the slot inboard end 161, 261 towards the slot outboard end 169, 269, the slot width value 180, 280 gradually increasing from the slot width-transition point 175, 275 to the slot outboard end 169, 269; the first particle removal device 150 coupled to a vacuum source 190 and the second particle removal device 250 coupled to a vacuum source 290; the first slot 160 positioned proximate to the imaging drum surface 16 to provide a first air flow 91 and the second slot 260 positioned proximate to the imaging drum surface 16 to provide a second air flow 92; where the marking material comprises ink.
In one embodiment of the third aspect of the invention, the imaging drum 10 comprises a transfix drum, the image transfer site 0 comprising a transfix site, the one or more marking material dispensers 70 comprising one or more ink jet print heads; the slot length 170, 270 being about 335 mm; the slot width inboard value being about 3.17 mm at the slot inboard end 161, 261; the slot width outboard value being about 6.33 mm at the slot outboard end 169, 269; and the slot constant-width portion length being about 150 mm.
The table below lists the drawing element reference numbers together with their corresponding written description:
Ref. No.: Description:
While various embodiments of an image forming device arranged with plural particle removal devices, in accordance with the present invention, are described above, the scope of the invention is defined by the following claims.
The disclosure of U.S. Pat. No. 6,070,026, “Charging device with separate pressure and vacuum air flows”, issued 30 May 2000 to Alfred J. Clafflin, Jr. et al., hereby is incorporated by reference, verbatim, and with the same effect as though the same disclosure were fully and completely set forth herein.