US20050015987A1

US20050015987A1 - Metering roller for fuser release oil applicator

Info

Publication number: US20050015987A1
Application number: US10/887,497
Authority: US
Inventors: Richard Berg
Original assignee: Eastman Kodak Co
Current assignee: Eastman Kodak Co
Priority date: 2003-07-17
Filing date: 2004-07-07
Publication date: 2005-01-27

Abstract

A metering roller, for a fuser release oil applicator, which enables precise and consistent application of a predetermined target amount of release oil to the fuser roller. Starting with tubing stock that has been machined and course ground to a final outside diameter, the metering roller is produced by initial pre-finish polishing, electroplating with Nickel, heat treatment to achieve a hardened surface, and final post-finish polishing. Both pre-finish and post-finish polishing steps are performed on a lathe with continuously fed polishing paper according to a parameter recipe that includes lathe spindle rpm and lead screw speed, and polishing paper grit, feed rate, pressure, and oscillatory rate.

Description

FIELD OF THE INVENTION

This invention relates generally to electrostatographic reproduction apparatus, and more particularly, to metering rollers in fuser release oil applicators.

BACKGROUND OF THE INVENTION

In typical electrostatographic reproduction apparatus, a latent image charge pattern is formed on a uniformly charged charge-retentive member or photoconductor having dielectric characteristics. Charged thermoplastic, pigmented marking particles are attracted to the latent image charge pattern to render the latent image visible. A receiver member, such as a sheet of paper, transparency, or other medium, is then brought into contact with the photoconductive member, and an electric field applied to transfer the marking particle developed image to the receiver member from the photoconductive member. The electric field to transfer the marking particle developed image to the receiver member from the photoconductive member is typically applied by spraying the backside of the receiver member with electrically charged ions from a corona charging device, or, alternatively, by contacting the backside of the receiver member with an electrically biased roller. The receiver member could, alternatively, be carried on a transport member such as a flexible belt, in which case the electrically biased transfer roller contacts the backside of the transport member that is interposed between the electrically biased transfer roller and the receiver member. Another alternative is to first transfer the marking particle developed image directly to an electrically biased intermediate transfer member in the form of a roller or belt and then from the intermediate transfer member to the receiver member.
After transfer to the receiver member, by any of the above alternatives, the receiver member bearing the transferred marking particle image is transported to a fusing station where the marking particle image is fused to the receiver member, typically by heat and pressure, to form a permanent reproduction on the receiver member. To print an image on both sides of the receiver member, hereafter referred to as duplex printing, a fused marking particle image is formed on side one of the receiver member by the above process, whereafter the receiver member is returned to the process via a duplex return path wherein the receiver member is turned over so as to have a second marking particle developed image transferred and fused to side two of the receiver member.
The fusing station includes a fuser member, which can be a roller, belt, or any surface having a suitable shape for fixing thermoplastic marking particles to the receiver member. The fusing step using a roller fuser member commonly includes passing the receiver member, with the marking particle image thereon, between a pair of engaged rollers that produce an area of pressure contact known as a fusing nip. In order to form the fusing nip, at least one of the rollers typically includes a compliant or conformable layer. Heat is transferred from at least one of the rollers to the marking particles in the fusing nip, causing the marking particles to partially melt and attach to the receiver member. In the case where the fuser member is a deformable heated roller, a resilient elastomeric layer is typically bonded to the core of the roller, with the roller having a smooth outer surface. Where the fuser member is in the form of a belt, e.g., a flexible endless belt that passes around the heated roller, it typically has a smooth outer surface, which may also be hardened.
Simplex fusing stations fuse marking particles to only one side of the receiver member at a time. In this type of station, the engaged roller that contacts the unfused marking particles is commonly known as the fuser roller and is a heated roller. The roller that contacts the other side of the receiver member is known as the pressure roller and is usually unheated. Either or both rollers can have a compliant layer on or near the surface. It is common for one of these rollers to be rotated by an external source while the other roller is rotated frictionally by the nip engagement.
The most common type of fuser roller is internally heated, i.e., a source of heat is provided within the roller for fusing. Such a fuser roller generally has a hollow core, inside of which is located a source of heat, usually a lamp. Surrounding the core can be an elastomeric layer through which heat is conducted from the core to the surface, and the elastomeric layer typically contains fillers for enhanced thermal conductivity. In order to prevent the receiver member bearing the fused marking particle image from sticking to the fuser roller, release oil is typically applied to the fuser roller. The release oil is typically applied to the surface of the fuser roller by an oiling mechanism including a wick in contact with release oil in a reservoir, a metering roller which receives release oil from the wick, a blade which controls the amount of release oil on the metering roller, and a donor roller which transfers the release oil from the metering roller to the fuser roller.
In electrostatographic reproduction apparatus for printing high quality color images, besides fusing the pigmented marking particle image to render it permanent on the receiver member, an additional function of the fusing step is to impart a desired level of gloss to the fused image. The level of gloss imparted to the image by the fuser station is typically dependent upon such parameters as the surface finish on the fuser roller, the amount of release oil on the fuser roller, and the pressure between the fuser roller and the pressure roller. In high quality color electrostatographic reproduction apparatus it is critical that the predetermined target amount of release oil is applied to the fuser roller with consistent high precision and uniformity. If the amount of release oil applied to the fuser roller deviates too much from the predetermined target amount or if it becomes too non-uniform, image quality defects will occur in the output prints.
A primary problem associated with too much release oil on the fuser roller occurs during duplex printing runs. As described above, in duplex printing, a fused marking particle image is formed on side one of the receiver member, whereafter the receiver member is returned to the process via a duplex return path wherein the receiver member is turned over so as to have a second marking particle developed image transferred and fused to side two of the receiver member. When the marking particle image on side one of the receiver member is fused in the first pass through the fuser nip, the release oil film on the fuser roller splits, and some of the release oil transfers to side one of the receiver member. During subsequent transfer of a marking particle developed image to side two of the receiver member, if the electric field for transfer is applied by an electrically biased roller as described above, some of the fuser release oil from side one of the receiver member, which is now in contact with the biased roller, transfers to the surface of the biased roller. During a long duplex printing run a relatively large amount of fuser release oil can thereby accumulate on the biased roller. During times such as cycle-down, non-imaging skip frames, or recovery from receiver jams, the biased roller is in direct contact with the photoconductive member. During these times some of the fuser release oil accumulated on the biased roller during duplex printing transfers to the photoconductive member. Release oil on the photoconductive member causes several types of image quality defects including background and streaks due to non-uniform transfer from the photoconductive member to the receiver member. These release oil related problems during duplex printing occur much sooner if oil in excess of the predetermined target amount is being applied to the fuser roller.
As mentioned above, the amount of release oil on the fuser roller affects the gloss level imparted to the high quality color image during the fusing step. Therefore, if the amount of release oil being applied to the fuser roller deviates from the predetermined target amount, the gloss level of the image will also vary from the target level. This problem will occur during simplex and duplex printing.

SUMMARY OF THE INVENTION

In view of the above, this invention is directed to an improved metering roller for a fuser release oil applicator. The release oil metering roller of this invention enables precise and consistent application of a predetermined target amount of release oil to the fuser roller of an electrostatographic reproduction apparatus fuser, thus avoiding image quality defects that result when the amount of release oil being applied to the fuser roller deviates from the predetermined target amount. Applicant has discovered a novel method of providing a surface finish on the release oil metering roller of this invention, the parameters of which can be varied to achieve a predetermined target release oil metering rate from within a range of rates, and which, additionally, precisely maintains the target metering rate under varying operating conditions.
Starting with tubing stock that has been machined and course ground to a final outside diameter, the method of this invention includes the steps of pre-finish polishing of the machined and course ground tubing stock, electroplating of the tubing stock with Nickel, heat treatment of the plated tubing stock to achieve a hardened surface, and a final post-finish polishing of the hardened Nickel surface. Both pre-finish and post-finish polishing steps are performed on a lathe with continuously fed polishing paper according to a parameter recipe that includes the lathe spindle rpm and lead screw speed, and the polishing paper grit, feed rate, pressure, and oscillatory rate.
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

FIG. 1 shows a side elevational view of an exemplary prior art fusing station including an oiling roller mechanism with a metering roller; and
FIG. 2 shows a schematic diagram of a polishing apparatus for practicing the method of preparing the metering roller surface, according to the present invention.

DETAILED DESCRIPTION OF THE INVENTION

Fusing stations and fuser rollers for use therein, including metering roll surfaces prepared according to this invention are readily includable in typical electrostatographic reproduction machines of many types, such as for example electrophotographic color printers. Since such color printers are well known in the prior art, they will not be described at length herein, but only to the extent necessary for a full understanding of the instant invention.
The invention relates to an electrostatographic reproduction or printing machine for forming a toner image on a receiver member and utilizing a fusing station employing a deformable fuser member for thermally fusing or fixing the toner image to a receiver member, e.g., of paper. The deformable fuser member can be a roller, belt, or any surface having a suitable deformable shape for fixing thermoplastic toner powder to the receiver member. The fusing station preferably includes two rollers which are engaged to form a fusing nip in which an elastically deformable fuser roller comes into direct contact with an unfused toner image as the receiver member is being frictionally moved through the nip. The fuser roller may be heated by an external source of heat, such as by direct contact with one or more heating rollers. Alternatively, the fuser roller may be heated via absorbed radiation, e.g., as provided by one or more lamps, or by any other suitable external source of heat. The toner image in an unfused state may include a single-color toner or it may include a composite image of at least two single-color toner images, e.g., a full color composite image made for example from superimposed black, cyan, magenta, and yellow single-color toner images. The unfused toner image is previously transferred, e.g., electrostatically, to the receiver member from one or more toner image bearing members such as primary image-forming members or intermediate transfer members. It is well established that for high quality electrostatographic color imaging with dry toners, small toner particles are necessary.
The fusing station and fuser roller of the invention are suitable for the fusing of dry toner particles having a mean volume weighted diameter in a range of approximately between 2 mm-9 mm, and more typically, about 7 mm-9 mm, but the invention is not restricted to these size ranges. The fusing temperature to fuse such particles included in a toner image on a receiver member is typically in a range 100° C. -200° C., and more usually, 140°-180° C., but the invention is not restricted to these temperature ranges.
The electrostatographic reproduction or printing apparatus may utilize a photoconductive electrophotographic primary image-forming member or a non-photoconductive electrographic primary image-forming member. Particulate dry or liquid toners may be used.
Turning now to the figures, FIG. 1 illustrates an exemplary simplex fusing station well known in the prior art, indicated generally by the numeral 100. The fusing station includes an externally heated, elastically deformable fuser roller 10, engaged under pressure with a relatively harder, i.e., relatively nondeformable, pressure roller 20 so as to form a fusing nip 25. The fuser roller, described in detail below, is a multilayer roller incorporating a heat storage layer. Fuser roller 10 is externally heated by direct contact with one or more heating rollers, e.g., rollers 30 and 35. (Pressure roller 20, though not heated by any dedicated internal or external source of heat, is generally indirectly heated to a certain extent via contact in the nip 25). A receiver member 15 carrying an unfused toner image 16 is shown moving in direction of arrow A, towards the fusing nip 25 for passage therethrough. Receiver member 15 is made of any suitable material, e.g., of paper or plastic, and the receiver member can be in cut sheet form (as depicted) or be a continuous web.
Fuser roller 10 generally includes a rigid, cylindrical, core member 11, around which is a deformable annular structure 12 including at least one elastomeric layer. The core member 11 is preferably made of a thermally conductive material such as a metal, preferably aluminum, and the core member is typically (but not necessarily) hollow as shown. Preferably an outer diameter of the core member is in a range between about 5 inches and 7 inches, and the outer diameter is more preferably about 6.0 inches. The deformable annular structure 12 includes an elastomeric base cushion layer closest to core member 11, a flexible heat storage layer around the base cushion layer, and, a thin flexible outer gloss control layer (release layer) around the heat storage layer (individual layers of structure 12 not separately shown). Preferably, the individual layers of structure 12 are successively coated on the core member 11 by using suitable coating techniques and post-coating curing and grindings of each successive layer as may be necessary. The outer release layer (gloss control layer) is preferably made of a low surface energy material such as for example a polyfluorocarbon, and preferably has a very smooth surface suitable for glossing the fused toner image. Preferably, the total thickness of the deformable annular structure 12 is in a range of approximately 0.180 inch −0.240 inch, although a total thickness outside of this range is not excluded.
It is important to have a contact width in nip 25 which is large so as to effect efficient transfer of heat from fuser roller 10 to the toner image 16. The contact width in nip 25 is preferably in a range of approximately between 15 mm-25 mm, and more preferably, 17 mm-19 mm.
Pressure roller 20 includes a rigid, cylindrical, core member 21 around which is an annular structure 22 including one or more layers, with the core member 21 usually made of a metal, preferably aluminum, and typically (but not necessarily) hollow as shown. Preferably an outer diameter of the core member 21 is in a range between about 3 inches and 4 inches, and the outer diameter is more preferably about 3.5 inches. A preferred annular structure 22 includes a resilient base cushion layer and an outer layer around the base cushion layer (individual layers of structure 22 not separately shown). The base cushion layer of annular structure 22 preferably has a thickness in a range of approximately between 0.18 inch and 0.22 inch, and the thickness is more preferably about 0.20 inch. The base cushion layer of structure 22 can for example be made of a commercially available condensation-crosslinked PDMS elastomer which contains about 32-37 volume percent aluminum oxide filler and about 2-6 volume percent iron oxide filler, sold by Emerson and Cuming (Lexington, Mass.) under the trade name EC 4952. Preferably the base cushion layer of structure 22 is coated on the core member 21 and the outer layer of structure 22 is formed as a topcoat layer on the underlying base cushion layer, with the topcoat layer preferably made of a fluorocarbon thermoplastic random copolymer (FLC) material such as for example the copolymer of vinylidene fluoride, tetrafluoroethylene and hexafluoropropylene disclosed in Chen, et al. U.S. Pat. No. 6,429,249, issued Aug. 6, 2002. The topcoat layer thickness is preferably in a range of approximately between 0.001 inch-0.004 inches, and more preferably 0.0015 inch-0.0025 inch. A suitable pressure roller 20 is preferably similar to the pressure roller disclosed in Chen, et al. U.S. Pat. No. 6,660,351, issued Dec. 9, 2003. Due to the incorporated fillers, the EC 4952 material usable for the base cushion layer of structure 22 has a relatively high nominal thermal conductivity of about 0.35 BTU/hr/ft/° F. However, the thermal conductivity of the base cushion layer of structure 22 is not critical to the operation of fusing station 100. In certain circumstances, a considerably lower thermal conductivity of the base cushion layer of structure 22 may be preferable so as not to drain too much heat from the contact zone of nip 25. A preferred base cushion layer of pressure roller 20 is made of an elastomeric material having any suitable thermal conductivity, which elastomeric material has a Shore A hardness greater than about 50, preferably greater than about 60. The base cushion layer may include a particulate filler.
The external heating roller 30 is preferably a hard, thermally conductive, roller. It is preferred that roller 30 be made of an annular aluminum member 31 with the outer surface (in contact with fuser roller 10) being preferably anodized. Within the interior hollow of member 31 is a source of heat, which source of heat is preferably a tubular heating lamp 32 coaxially located along the central longitudinal axis of member 31. Ohmic heating of filament 34 included in lamp 32 is controlled by a programmable power supply (not shown) so as to provide variable heating power, either continuously or intermittently. Any suitable outer diameter of roller 30 may be used, with a preferred outer diameter being about 1.0 inch. Heating roller 35 includes member 36 and lamp 37 which are respectively entirely similar to member 31 and lamp 32 of roller 30, with a filament 39 of lamp 37 similarly controlled by a programmable power supply (not shown). Both rollers 30 and 35 are frictionally driven by the fuser roller 10 and are engaged under pressure to form respective heating nips 33 and 38. The contact zone of each of nips 33 and 38 has a width, which is preferably in a range of approximately between 10 mm-12 mm, and more preferably about 11 mm. Preferably, the operating temperature of heating rollers 30 and 35 is in a range of approximately 230° C.-270° C., resulting in a surface temperature of the fuser roller 10 which is preferably in a range of approximately between 140° C.-170° C., with the required surface temperature in this range being dependent on the thickness of the receiver members passing through nip 25. These surface temperatures are suitable for well-known polyester toners, yet may require small adjustments for different types of toners or unusual receiver member materials.
The surface temperatures of the heating rollers 30 and 35 and the fuser roller 10 are preferably measured by any suitable temperature sensing devices external to the rollers (not shown), such as for example contacting sensors, in contact with each of the fuser roller and heating rollers. Alternatively, non-contacting temperature sensors, e.g., infrared sensors, can be used with any of these rollers. Preferably, each temperature-sensing device can be connected to a controller (not shown) for controlling the surface temperature of the respective roller.
A heating roller cleaning station 50 includes a cleaning web 55 for cleaning the surface of the fuser roller 10, a take-out spool 53 from which web 55 is unwindable, and a take-up spool 54 upon which web 55 is windable. The heating roller cleaning station 50 further includes pressure backup rollers 51 and 52 for tensing the cleaning web 55 against the respective heating rollers 30 and 35. Alternatively, a single backup roller may be used (not illustrated) which presses against both the heating rollers 30 and 35. Web 50 is typically a single-use web such that the entire cleaning web is discarded when the take-out spool 53 is exhausted. The web 50 may be made of any suitable material, such as for example a polyethyleneterephthalate (PET) woven fiber sold under the tradename Nomex from DuPont.
Within the interior hollow of core member 11 is an auxiliary optionally activated source of heat, which internal source of heat is preferably a tubular heating lamp 13 coaxially located along the central longitudinal axis of core member 11, the lamp 13 including a filament 14. Intermittent or variable ohmic heating (as may be required) of filament 14 is controllable by a programmable power supply (not shown). The auxiliary optionally activated source of heat or lamp 13 can be used intermittently so as to augment or supplant the heating provided by the external heating rollers 30 and 35. For example, the lamp 13 can be turned on when an electrostatographic printer is in standby mode in order to keep the fuser roller 10 suitably warn, so that when the printer is restarted the heating rollers 30 and 35 can rapidly restore steady state thermal conditions for fusing. Conversely, when steady state has been achieved after a start-up, any auxiliary heating may be reduced or shut off as may be necessary. The lamp 13 can also be suitably activated so as to avoid a fusing defect known as “droop”, which is the result of inadequate fusing caused by a thermal transient when cold receiver members first enter the fusing nip 25 after start-up of the printer after a stand-by or a shutdown.
Operating in conjunction with fusing roller 10 is an oiling roller mechanism 40 including a wick 46 in contact with a liquid release agent (e.g., fuser oil) 43 contained in reservoir 44. Wick 46 absorbs the release agent 43 and transfers the release agent to a metering roller 48, with the amount of release agent on the surface of roller 48 controlled by blade 49. Metering roller 48 is in contact with a release-agent-donor roller 47, which release-agent-donor roller contacts fuser roller 10 and thereby delivers to the surface of the fuser roller a continuous flow of release agent 43. A preferred donor roller is similar to that of Chen, et al. U.S. Pat. No. 6,721,529, issued Apr. 13, 2004. Approximately 1-20 milligrams of release agent 43 is needed for each receiver member (e.g., receiver member sheet 15) passing through nip 25. As is well known, a suitable release agent is typically a silicone oil. A preferred polymeric release agent 43 for use in fusing station 100 is an amine-functionalized polydimethylsiloxane having a preferred viscosity of about 300 centipoise as disclosed in Chen, et al. U.S. Pat. No. 6,190,771, issued Feb. 20, 2001. A suitable release-agent-donor roller 47 for use in fusing station 10 includes for example a hollow aluminum core of outer diameter about 0.875 inch, the core coated by a cushion layer about 0.230 inch thick made of a compliant material having a low thermal conductivity such as for example obtainable commercially as S5100 from Emerson and Cuming (Lexington, Mass.), with a release layer about 0.0025 inch thick coated on the cushion layer (individual layers not illustrated in FIG. 1). The release layer can be made from an interpenetrating network composed of a crosslinked fluoroelastomer and two different silicone elastomers such as disclosed in Davis, et al. U.S. Pat. No. 6,225,409, issued May 1, 2001. More preferably, the release layer is made of a copolymer of vinylidene fluoride, tetrafluoroethylene and hexafluoropropylene as disclosed in Chen, et al. U.S. Pat. No. 6,429,249, issued Aug. 6, 2002. Any suitable dimensions of the core, cushion layer, and release layer may be used.
A release aid mechanism such as for example air knives 61 and 62 can be provided to aid release of a fused receiver member after passage of the receiver member through the fusing nip 25, with pressured air from air knife 61 generally directed towards the surface of fuser roller 10 and pressured air from air knife 62 generally directed towards the surface of pressure roller 20. Alternatively, any suitable release aid mechanism for preventing the fused receiver member from wrapping on one or other of rollers 10 and 20 may be used, including skives, blades, and so forth.
As mentioned above, typically approximately 1-20 milligrams of release agent 43 is needed to be delivered to the fuser roller 10 for each receiver member 15 passing through nip 25. The precise amount of release agent 43 required depends upon several factors including the material and thickness of receiver member 15, the velocity at which receiver member moves through nip 25, the temperature of the fuser roller 10, the specific rheological properties of the toner in unfused toner image 16, and the desired gloss level of toner image 16 after fusing. Typically the target amount of release agent 43 applied to fuser roller 10 must be held to a tolerance of ±1.25 milligram per receiver member 15 in order to maintain reliable performance of fusing station 100 and consistent image quality of the fused toner image on receiver member 15. One of the factors that critically affects the amount of release agent 43 applied to fuser roller 10 by oiling roller mechanism 40 is the surface finish on metering roller 48. Applicant has discovered a method of providing a surface finish to metering roller 48, the parameters of which can be varied to achieve, from within a range, a predetermined target amount of release agent 43 per receiver member 15, and which, additionally, precisely maintains the target amount under varying operating conditions.
Starting with the raw cylindrical stock, which is to become a metering roller by the method of this invention, the first step is to grind the raw stock, for example in a lathe, to a predetermined outside diameter. In the preferred embodiment of this invention described herein the starting raw stock is stainless steel, but it should be understood that any other metal could be used as the starting raw stock. The remaining steps in the method of the present invention include a pre-finish polishing step performed on the stock that was ground to the final diameter in step one, plating the pre-finish polished stock with a harder material such as, for example, chrome or nickel, and a final post-finish polishing of the plated stock to create the finished metering roller.
Attention is now drawn to FIG. 2, which shows a schematic of an example of an apparatus in which both the pre-finish and post-finish polishing steps of the method of this invention may be performed. In FIG. 2, numeral 200 designates the work piece in one of either the pre-finish or post-finish polishing steps. The work piece is rotated, for example in a lathe, in the direction indicated by arrow A, at a speed in the range 500-1000 rpm. Polishing apparatus, designated collectively by numeral 205, engages rotating work piece 200. The abrasive in the polishing steps comprises Aluminum Oxide bonded to outer surface 215 of flexible belt 210. Flexible belt 210 is fed from supply roll 220 to take-up roll 225, in the direction indicated by arrows B and C, in a path defined by rollers 230, 235, 240, and 245. The feed rate of flexible belt 210 from supply roll 220 to take-up roll 225 is in the range 2-4 inches per minute. The grit grade of the Aluminum Oxide abrasive on surface 215 is in the range 9-30 microns. Exemplary of a commercially available abrasive that may be used in the method of this invention is 3M™ Microfinishing Film-373L. The Aluminum Oxide abrasive on surface 215 of flexible belt 210 is engaged with rotating work piece 200 by roller 235, with a pressure in the range 10-15 psi. The complete polishing apparatus 205 comprising Aluminum Oxide abrasive on surface 215 of flexible belt 210, feed roll 220, rollers 230, 235, 240, 245, and take-up roll 225, axially traverses rotating work piece 200, at a steady speed in the range 25-35 inches per minute, while simultaneously oscillating axially at an oscillation rate in the range 70-90 cycles per second.
Following a pre-finish polishing step in the apparatus described above, work piece 200 is electroplated with Nickel to a minimum thickness 25.4 microns. The work piece 200 is then heat treated by steadily increasing the temperature of the work piece from ambient temperature to 750° F. in one hour, maintaining the temperature at 750° F. for three hours, and steadily cooling the temperature from 750° F. to ambient temperature in one hour, thereby resulting in a surface hardness of the work piece in the range 69÷4 Rockwell C. The plated and heat treated work piece 200 is then subjected to a post-finish polishing step in the apparatus described above and depicted in FIG. 2.
When a roller prepared by the method of the present invention, described above, is used as the metering roller 48 in oiling roller mechanism 40 in FIG. 1, an oiling application rate to fuser roller 10 in the range 1.5-6.0 milligrams per receiver member can be achieved by appropriate selection of the parameters of the method of this invention. Moreover, the target oiling rate selected will be held to a tolerance less than ±1.25 milligrams per receiver member. The parameters of the method of this invention that control the target oiling rate include the grit grade of the Aluminum Oxide abrasive on surface 215 of flexible belt 210, the feed rate of flexible belt 210 from supply roll 220 to take-up roll 225, the pressure with which roller 235 is applied to work piece 200, the steady rate at which the polishing apparatus 205 axially traverses work piece 200, and the rated at which the polishing apparatus 205 axially oscillates.

EXAMPLE

An exemplary metering roller according to the method of this invention was prepared as follows:
1. 316 L Stainless Steel tubing stock was ground to an outside diameter of 30.1 mm.
2. The ground tubing stock was pre-finish polished by the method described above and depicted in FIG. 2 with the following set of parameters:

- Tubing stock rotational speed—570 rpm,
- Aluminum Oxide abrasive grit—30 microns,
- Flexible belt feed rate—4.0 inches/minute,
- Pressure applies to tubing stock by roller 235—13 psi,
- Steady axial speed of polishing apparatus—35 inches/minute,
- Axial oscillating speed of polishing—8.3 cycles/second.

3. The pre-finished tubing stock was electroplated with Nickel to a thickness of 8 microns.
4. The plated tubing stock was heat treated by steadily increasing the temperature of the stock from ambient temperature to 750° F. in one hour, maintaining the temperature at 750° F. for three hours, and steadily cooling the temperature from 750° F. to ambient temperature in one hour, thereby resulting in a surface hardness of the stock of 69 Rockwell C.
5. The heat-treated tubing stock was post-finish polished by the method described above and depicted in FIG. 2 with the following set of parameters:

- Tubing stock rotational speed—1000 rpm,
- Aluminum Oxide abrasive grit—30 microns,
- Flexible belt feed rate—2.2 inches/minute,
- Pressure applies to tubing stock by roller 235—10 psi,
- Steady axial speed of polishing apparatus—25 inches/minute,
- Axial oscillating speed of polishing—8.3 cycles/second.

The metering roller made as described above was tested in an apparatus similar to fusing station 100 in FIG. 1, as the metering roller 48 in oiling roller mechanism 40. The fusing station 100 was substantially that used in a NexPress 2100 digital printing press. In printing runs as long as 100,000 prints, the rate of release oil application to fuser roller 10 was 5.1 milligrams per receiver sheet, and held to a tolerance of ±1.25 milligrams per receiver sheet.
The invention has been described in detail with particular reference to certain preferred embodiments thereof, but it will be understood that variations and modifications can be effected within the spirit and scope of the invention.

Claims

1. A method of making a metering roller, from a cylindrical work piece of a predetermined outside diameter, for delivering release fluid to a contact fusing device, comprising the steps of:

a. polishing the axial surface of the cylindrical work piece to a predetermined initial surface finish;

b. increasing the hardness of said axial surface; and

d. polishing said axial surface of the cylindrical work piece to a predetermined final surface finish.

2. The method of claim 1, wherein in step b said axial surface is electroplated with Chrome.

3. The method of claim 2, wherein said Electroless Nickel is plated to a minimum thickness of 25.4 microns.

4. The method of claim 2, wherein the polishing abrasive used in steps a and c is Aluminum Oxide, with a grit grade in the range of 9-30 microns, bonded on a flexible film.

5. The method of claim 4, wherein in steps a and c the work piece is rotated at a speed in the range 500-1000 rpm.

6. The method of claim 5, wherein said Aluminum Oxide polishing abrasive engages the work piece via a backing roller, at a pressure in the range 9-15 psi.

7. The method of claim 5, wherein said Aluminum Oxide polishing abrasive is fed from a supply roll to a take-up roll at a speed in the range 2-4 inches per minute.

8. The method of claim 5, wherein said Aluminum Oxide polishing abrasive axially traverses the work piece at a speed in the range 25-35 inches per minute, and axially oscillates at a rate in the range 7.0-9.0 cycles per second.

9. The method of claim 5, wherein said Aluminum Oxide polishing abrasive engages the work piece via a backing roller, at a pressure in the range 9-15 psi, is fed from a supply roll to a take-up roll at a speed in the range 2-4 inches per minute, axially traverses the work piece at a speed in the range 25-35 inches per minute, and axially oscillates at a rate in the range 7.0-9.0 cycles per second.

10. The method of claim 1, wherein in step c said axial surface is electroplated with Nickel.

11. The method of claim 10, wherein the work piece is heat treated by steadily raising the temperature of the work piece from ambient temperature to 750° F. in one hour, maintaining the temperature at 750° F. for three hours, and steadily cooling the temperature from 750° F. to ambient temperature in one hour.

12. The method of claim 11, wherein said Nickel is plated to a minimum thickness 25.4 microns.

13. The method of claim 11, wherein the polishing abrasive used in steps a and c is Aluminum Oxide, with a grit grade in the range of 9-30 microns, bonded on a flexible film.

14. The method of claim 13, wherein in steps a and c the work piece is rotated at a speed in the range 500-1000 rpm.

15. The method of claim 14, wherein said Aluminum Oxide polishing abrasive engages the work piece via a backing roller, at a pressure in the range 9-15 psi.

16. The method of claim 14, wherein said Aluminum Oxide polishing abrasive is fed from a supply roll to a take-up roll at a speed in the range 2-4 inches per minute.

17. The method of claim 14, wherein said Aluminum Oxide polishing abrasive axially traverses the work piece at a speed in the range 25-35 inches per minute, and axially oscillates at a rate in the range 7.0-9.0 cycles per second.

18. The method of claim 14, wherein said Aluminum Oxide polishing abrasive engages the work piece via a backing roller, at a pressure in the range 9-15 psi, is fed from a supply roll to a take-up roll at a speed in the range 2-4 inches per minute, axially traverses the work piece at a speed in the range 25-35 inches per minute, and axially oscillates at a rate in the range 7.0-9.0 cycles per second.

19. A metering roller, for delivering release fluid to a contact fusing device, made by the method of claim 1.

20. A device, for applying release fluid, contained in a sump, to a contact fusing device, comprising:

a donor roller rotatably supported to contact said fusing device;

a metering roller made by the method of claim 1, said metering roller rotatably supported to contact said donor roller and said release fluid in said sump; and

a metering blade contacting said metering roller for metering said release fluid to a predetermined thickness.