Lubricant coating device and image forming apparatus incorporating the lubricant coating device

A lubricant supplying device comprises a solid lubricant, a lubricant applicator to scrape and supply the lubricant to a target, and a pressing mechanism to press the solid lubricant against the lubricant applicator. An amount of pressure applied to the solid lubricant by the pressing mechanism increases until one of a thickness of the solid lubricant and a number of printed sheets reaches a prescribed level after the lubricant starts being consumed.

CROSS REFERENCE TO RELATED APPLICATIONS

This application claims priority pursuant to 35 USC §119 to Japanese Patent Application No. 2010-058478, filed on Mar. 15, 2010, the entire contents of which are herein incorporated by reference.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a lubricant coating device and an image forming apparatus, and in particular, to a lubricant supplying mechanism disposed in a lubricant coating device and an image forming apparatus.

2. Description of the Background Art

As is well know, in an image forming apparatus, such as a copier, a printer, a duplicator, etc., there is provided a lubricant supply system that supplies lubricant to a photoconductive member and an intermediate transfer belt to decrease a friction resistance generally caused during a cleaning process for cleaning the photoconductive member and the intermediate transfer belt after an image transfer process in order to prevent a porous image from being transferred therefrom in a transfer process as described in Japanese Patent Application Laid Open No. 2001-305907 (JP-2001-305907-A).

Such lubricant is scraped and supplied to the photoconductive member and/or the transfer belt by a supplying brush in rotary contact therewith. However, when the lubricant is consumed and a thickness thereof decreases, a contact condition of the supplying brush in contact with the lubricant becomes unstable, and a supplying amount thereof possibly becomes unsteady as well.

To avoid, such a problem, a prescribed system can be employed, in which a pair of elastic members, such as springs, etc., press the lubricant at both its lengthwise ends, respectively, toward the supplying brush with its axis aligned with a normal line of the supplying brush.

However, an elastic force possibly decreases as the lubricant is consumed in proportion to an expansion amount of the spring. In addition, when an abrasion amount of the lubricant is different between the lengthwise ends, supplying amount therefrom is also different from each other.

To avoid such a problem, the applicant has proposed a system capable of uniformly supplying a prescribed amount of lubricant from the entire lengthwise portion thereof as described in Japanese Patent Application Laid Open No. 2007-293240 (JP-2007-293240-A), which is submitted as IDS. Therefore, the description of the system is herein incorporated by reference.

However, it is realized that avoiding deterioration of a supplying brush as time elapses is important to maintain a preferable contact condition of the lubricant in contact with the supplying brush.

Because, when the supplying brush scrapes off the lubricant by friction therebetween and supplies it to a target, bristles of the brush sometimes deform and flattened due to the friction resistance as time elapses.

Nor can this problem be solved simply by maintaining the pressure of the lubricant against the supplying brush at a prescribed constant level using the above-described technology. Thus, for example, when the supplying brush bites hard into the lubricant, the bristles of the brush tend to flattened more. As a result, the amount of lubricant to be supplied possibly largely decreases. To minimize such flattering and deformation, the invasion amount can be decreased. However, because the contact condition of the brush in contact with the lubricant becomes unstable at light pressure because the brush is not perfectly round, lubricant supply becomes unstable.

SUMMARY OF THE PRESENT INVENTION

Accordingly, an object of the present invention is to address and resolve such and other problems and provide a new and novel lubricant supplying device that comprises a solid lubricant, a lubricant applicator to scrape and supply the lubricant to a target, and a pressing mechanism to press the solid lubricant against the lubricant applicator. An amount of pressure applied to the solid lubricant by the pressing mechanism increases until one of a thickness of the solid lubricant and a number of printed sheets reaches a prescribed level after the lubricant starts being consumed.

The pressing mechanism includes a bias device to provide a bias, and plural pressing members to receive the bias from the bias device and symmetrically press the solid lubricant at two positions thereof about a contact center in a prescribed pressing direction. A direction of the bias is perpendicular to the prescribed pressing direction. Each of the plural pressing members has a fulcrum and is freely swingable therearound. An angle formed by an extension line extending through an operation point and the fulcrum provided in each of the plural pressing members and the prescribed pressing direction decreases while an angle formed by an extension line extending through a power point and the fulcrum provided in each of the plural pressing members and the prescribed biasing direction increases as the solid lubricant is scraped and an amount thereof decreases. The operation point contacts a base of the lubricant supplying device via its contact section and the power point receives the bias of the bias device.

In yet another aspect, the power point is located to meet the following inequation when “A” is calculated by the following equality;
Ae/As>Fs/Fe,
and
“A”=(X×Y)/L2,
wherein X represents a horizontal distance between the operation point and the fulcrum, Y represents a vertical distance between the power point and the fulcrum, L represents a distance between the operation point and the fulcrum, F represents a bias force of the bias device, and suffixes “s” and “e” represent initial and final values, respectively.

In yet another aspect, the contact section of the pressing member is one of point and area contact sections.

In yet another aspect, the contact section of the pressing member has a circular shape.

In yet another aspect, plural pressing members press the target via a lubricant holder.

In yet another aspect, the lubricant applicator is a brush.

In yet another aspect, the pressing mechanism is enabled to press the solid lubricant so that an invasion amount thereof into the brush is about 10% and more of a natural length of a bristles of the brush.

In yet another aspect, a leveling member is provided to contact a surface of the target and level the solid lubricant when the lubricant is supplied thereon.

PREFERRED EMBODIMENTS OF THE PRESENT INVENTION

Referring now to the drawing, wherein like reference numerals designate identical or corresponding parts throughout several views, in particular, inFIG. 1, a configuration of an image forming apparatus according to one embodiment of the present invention is described. As shown, an image forming apparatus100is a tandem type that includes an endless intermediate transfer belt serving as an image bearer capable of bearing a toner image thereon and plural image formation stations arranged side by side along a stretching surface of the intermediate transfer belt. Below an image formation section A in the image forming apparatus100, there is provided a sheet feeding bank B accommodating sheets serving as a recording medium.

In an image formation section A, there is provided an intermediate transfer belt1, which is wound around plural rollers2A to2F and is conveyed by the driving roller2A In a direction shown by an arrow in the drawing. A stretching surface of the intermediate transfer belt1is partially bent to an inner circumferential surface side thereof by the roller2F to create a space for disposing a below described fixing device10, so that the height of the image forming apparatus is decreased. Plural image formation stations capable of respectively forming different color images are arranged side by side facing one of the stretching surfaces of the intermediate transfer belt1.

The respective image forming stations have substantially the same configuration as others, and the black color image forming station K is typically described hereinafter. There is provided a rotatable photoconductive drum3in the image forming station. Around the photoconductive drum3, a charger4, a developing device5, and a cleaner6are arranged collectively constituting a process cartridge.

Above the image forming stations, there is disposed a writing device7including a laser source for emitting a writing light to the photoconductive drum3in accordance with image information via an optical system. At positions opposing the photo-conductive drums3via the intermediate transfer belt1in the respective image forming stations, there are provided primary transfer rollers8as a primary transfer device.

A secondary transfer roller9as a secondary transfer member is disposed downstream of the image forming station opposing a transfer backside roller2B via the intermediate transfer belt1. The secondary transfer roller9transfers an image superimposed on the intermediate transfer belt at once onto a sheet launched from the sheet feeding bank B. The fixing device10is disposed downstream of the secondary transfer roller9to fix a toner image onto the transfer member conveyed there by a below described conveyance device200.

The fixing device10is a belt type including a heating roller10A, a fixing roller10B, a fixing belt10C wound around the heating roller10A and the fixing roller10B, and a pressing roller10D opposing the fixing roller10B. Since calorie of a belt is small, a warm up time reaching a prescribed temperature is decreased. During pinching and conveying the transfer member between the fixing and pressing rollers10B and10D in the fixing device10, heat and pressure is applied thereto, so that the toner image bored thereon is fused and penetrates thereby being fixed.

The transfer member having been subjected to the fixing process is conveyed toward a sheet ejection tray100A disposed at an outside of the image forming apparatus or toward a reversion conveyance device RP to execute duplex copying.

Toner and alien substance, such as sheet dust, etc., remaining on the intermediate transfer belt1are removed by a belt cleaner11disposed in the vicinity of the bending section. The belt cleaner11of a configuration shownFIG. 1includes one of a cleaning blade11A, a roller, and a brush roller contacting the intermediate transfer belt1. A backup roller12is disposed on the inner circumferential surface side of the intermediate transfer belt1opposing the cleaner to expedite scraping efficiency of the cleaner scraping the alien substance.

Plural sheet feeding cassettes B1and B2are provided in the sheet feeding bank B each including a launching roller B3and a sheet feeding roller B4on the transfer member launching side therein. On the conveyance path for conveying the transfer member launched from the sheet feeding cassettes B1and B2, there is provided a registration roller13upstream of a secondary transfer section where a secondary transfer roller is disposed, so that the registration roller can launch the transfer member at a prescribed registration time to synchronize with an image position. Back toFIG. 1, C denotes a manual sheet feeding section. A conveyance path connected to the manual sheet feeding section C meets a conveyance path coming from the sheet feeding bank upstream of the registration roller13.

In the image forming apparatus100with such a configuration, when the photoconductive drum3is uniformly charged by the charger4and a writing light is emitted from the writing device7, a latent image is formed in the image forming station. Subsequently, toner supplied from the developing device5visualizes the latent image and generates a toner image.

The toner image born on the photoconductive drum3is transferred onto the intermediate transfer belt using a transfer bias provided by the primary transfer roller8. A toner image generated by superimposing respective images in the image forming stations is transferred at once by the secondary transfer roller9onto a transfer member launched from the sheet feeding bank B. The transfer member having completed the secondary transfer process is then conveyed toward the fixing device10by a later described conveyance device200. Subsequently, the toner image on the transfer member is fixed by the fixing device10and is then conveyed toward either the sheet ejection tray100A or the reversion conveyance device RP.

Completing the primary transfer process, the photoconductive drum3and intermediate transfer belt1are subjected to cleaning processes of the cleaners6and10disposed in the image forming station and the belt bending section, respectively, to prepare for the next image formation.

Now, an exemplary configuration of the cleaner for the intermediate transfer belt1is more specifically described with reference toFIG. 2. As described with reference toFIG. 1, the cleaner11is disposed opposing the intermediate transfer belt1downstream of the secondary transfer roller9in a moving direction of the intermediate transfer belt as shown by an arrow inFIG. 2.

In the cleaner11, an inlet seal11C preventing scattering of toner therefrom, a cleaning blade11A, and a brush roller11bare disposed on the upstream side therein in the intermediate transfer belt moving direction. The brushing roller11B is enabled to rotate counter to a moving direction of the intermediate transfer belt1to remove pre-transferred toner or alien substance, such as sheet dust, etc., sticking thereto in cooperation with a cleaning blade that is given tendency of contacting the intermediate transfer belt1by the pressing spring22A. In the drawing,14denotes a waste toner conveyance coil to eject waste toner to an outside of the cleaner.

A lubricant supplying device20is disposed on the downstream side of the intermediate transfer belt1in the cleaner11. The lubricant supplying device20includes a solid lubricant20A, a supplying brush roller20B including a bristles state rotator that rotates in a direction shown by an arrow and scrapes and coats the intermediate transfer belt1with the solid lubricant contacting the solid lubricant20A. Also included are a leveling cleaning blade20C that contacts the intermediate transfer belt to level and form a thin lubricant layer thereon, and a pressing spring20C1that provides tendency of contacting the intermediate transfer belt1to the leveling cleaning blade20C. At opposing sections to the above-described brush rollers11B and20B via the intermediate transfer belt1, cleaning opposing rollers12and12′ are disposed as backside pressure members.

The brush roller20B is made of PET bristles having fineness of about 200 T (deci Tex) to supply the solid lubricant20B to the surface of the intermediate transfer belt1. If the brush fineness is too high, rigidity thereof becomes too strong to obtain a sufficient amount of invasion thereof capable of absorbing fluctuation of a pressing force. Further, it is not preferable for a surface performance of a cleaning target if high rigidity brush bristles slide and contact the cleaning target. By contrast, when the brush fineness is too low, the lubricant excessively bites into the brush roller and flatten and deforms a brush. In this point of view, the brush fineness is preferably from about 100 to about 300 T.

The solid lubricant20A is biased against the brushing roller20B by a bias of the pressing spring employed in a later described pressing mechanism. The solid lubricant20A is made of fatty acid metal salt. The metal can be selected from zinc, iron, calcium, aluminum, lithium, magnesium, strontium, barium, cerium, titan, zirconium, lead, and manganese or the like. The fatty acid salt is selected from at least one of lauryl acid, stearic acid, palmitic acid, mysterium acid, and oleic acid or the like. Especially, zinc stearate and calcium stearate are more effective in view of friction reduction on an image bearer.

Now, the pressing mechanism30for pressing the solid lubricant20A is more specifically described with reference toFIG. 3, wherein only a left half thereof is illustrated because of its symmetric shape. As shown, a holder31holds the solid lubricant20A and includes a swinging fulcrum? around which the pressing member32made of polyacetal having a fine sliding performance swings.

Thus, the two pressing members32are symmetrically arranged in the vicinity of both ends of the lubricant20A about its lengthwise center, and are enabled to swing around supporting pins31A disposed on the holder31, respectively. The pressing member32includes a hook section32A between a base end having the supporting pin31A and its swinging end. A pressing spring33is hooked by the hook sections32A of the respective pressing members symmetrically arranged to pull these pressing members as described in Japanese Patent Application Laid Open No. 2007-293240 (JP-2007-293240-A) by the applicant, the description of which is incorporated herein.

Now, an exemplary characteristic configuration of a system in which a pressing member32presses a solid lubricant via a holder31that holds the lubricant20A is more specifically described.

As described below, one embodiment of the present invention is characterized in that an operation force N used as a pressing force is not maintained constant, but is increased until a thickness of the lubricant20A or a number of printed sheets reach a prescribed level from when the lubricant20A starts being consumed. More specifically, the hook section32A is positioned at a prescribed location where an angle formed by an extension line that extends through an operation point generating an operation force and the fulcrum of the pressing member32and the pressing direction of the solid lubricant20A decreases, while an angle formed by an extension line that extends through a power point receiving the bias of the pressing spring33and the fulcrum of the pressing member32and the biasing direction of the pressing spring33increases in accordance with decrease in thickness of the lubricant20A as a result of consumption thereof.

According to a characteristic configuration of one embodiment of the present invention,

the pressing member32has a circular arc shape at its swinging side end contacting a surface of a container casing34to receive a reaction force from the container casing34when contacting thereto to use it as an operation force N applied to the lubricant20A. Further, the lubricant20A is pressed by the pressing member32and contacts the brush bristles with the operation force N to create a bent of about 1 mm of the brush bristles when its natural length is about 5 mm.

Now, a change of an operation force N in accordance with changes of the power and operation points of the pressing member32is typically described with reference toFIG. 5. As shown, the operation force N is calculated by the following formula based on a balance of moments caused by distances from the fulcrum to the power and operation points;
N=(1/NL)Fsin φ cos θ

When considering that the distances from the fulcrum, which are parameters of the moments when the pressing member32swings, are represented by the following first two equations, the above-described operation force N is sought by the following second equation;
Lsin φ=Y, Cos θ=X/L,
and
N=F·(X·Y)/L2.

That is, an angle formed by an extension line that extends through an operation point and the fulcrum of the pressing member32and the pressing direction of the solid lubricant20A decreases, while an angle formed by an extension line that extends through a power point receiving the bias of the pressing spring33and the fulcrum of the pressing member32and the biasing direction of the pressing spring33increases, when the pressing member32swings sliding on the container casing34in accordance with a change in thickness of the lubricant20A as a result of consumption thereof.

In one embodiment of the present invention, to increase the operation force N in accordance with consumption amount of the solid lubricant20A from initial consumption stage to a terminating consumption stage in accordance with a change in angle of the pressing member32during its swinging?, the hook31A is positioned at a prescribed location on the pressing member32to meet the following inequation as shown inFIGS. 3 and 5when “A” is represented by the following equality;
Ae/As>Fs/Fe,
“A”=(X×Y)/L2
wherein X represents a horizontal distance between the operation point and the fulcrum, Y represents a vertical distance between the power point and the fulcrum, L represents a distance between the operation point and the fulcrum, F represents a bias force of the bias device, and suffixes “s” and “e” represent initial and time elapsing values, respectively. Further, Ts represents a thickness of the solid lubricant20A at its initial usage stage, where as Te represents that at its consumption terminating stage, wherein the below described relation is established.
Ts>Te

An exemplary condition of an increase in operation force caused by swinging movement of the pressing member32in the pressing mechanism30in accordance with a consumption amount of the solid lubricant20A is illustrated inFIG. 6.

As shown, when it is controlled to maintain a prescribed operation force, an amount of consumption of the solid lubricant20A gradually decreases. By contrast, an amount of consumption of the solid lubricant20A does not decrease very much in one embodiment of the present invention, because the operation force is gradually increased.

Specifically, according to one embodiment of the present invention, the above-described configuration is employed to intentionally avoid deterioration of contact of the brushing roller20B in contact with the solid lubricant20by supposing that tips of the bristles of the brushing roller20B are flattened and causes the deterioration as time elapses.

As a result, regardless of the flattering of the above-described brush hair, an amount of solid lubricant20A does not decrease.

Further, about 1.5 N is designated as an operation force in the consumption initial stage, i.e., an initial contact pressure of the brushing roller20B in contact with the solid lubricant20A, and about 2 N is designated as an operation force in the consumption final stage. In this situation, about 150 mg/Km, more preferably 100 mg/Km to 200 mg/Km, is designated as a consumption amount of the solid lubricant20A per unit running length of the intermediate transfer belt1as a cleaning objective to avoid transfer and cleaning malfunctions in the secondary transfer section and the cleaner, respectively, due to increase in a friction coefficient.

Instead of the above-described circular arc shape2, the swinging side end of the pressing member3can be area and point shapes as far as they can receive an operation force of a bias from the pressing spring33. For example, the side end shape having a corner can be exemplified even if X and Y distance values from the fulcrum slightly fluctuate as shown inFIG. 8.

Further, the lubricant supplying mechanism in the various embodiments can be applied to an image bearer, such as a photoconductive member, etc., in addition to the intermediate transfer belt as a cleaning target. In such a situation, it is preferable that a ratio of pressure increase of the pressing member is greater than when the photoconductive member is targeted that when the intermediate transfer belt is targeted for the reason as described below.

That is, when a toner image is transferred from the image bearer onto the intermediate transfer belt and a surface friction coefficient of the photoconductive member is higher than that of the intermediate transfer belt, a porous image is transferred in the transfer process as described in Japanese Patent Application Laid Open No. 2000-019858. Thus, the friction coefficient of the image bearer located upstream is preferably kept smaller. Consequently, an amount of lubricant to be supplied is preferably increased in proportion to an upper level of a position of a cleaner. However, it is known that an amount of the lubricant supplied changes from the initial stage as time elapses as shown inFIG. 9.

As shown, pressure of the lubricant against the brush in the condition A is twice as large as that of the condition B, so that an amount of lubricant supplied becomes greater in the condition A. Even though a difference in supplying amount in the initial stage is prominent between the conditions A and B, which is scarcely different later from each other as time elapses. Under the condition in that the difference in supply amount is scarcely different from each other, an intended surface friction coefficient cannot be obtained depending of an operation condition, such as image area rate, a number of consecutive sheet feeding, etc., and is a friction coefficient of the intermediate transfer member is possibly lower than that of the image bearer.

Accordingly, to maintain the surface friction coefficient of the toner image bearer located upstream to be lower even as time elapses, an increasing rate of pressure of the lubricant supplying device is preferably large in proportion to an upstream level thereof from the initial stage as time elapses. Consequently, the surface friction coefficient of the image bearer located upstream can be maintained to be lower even as time elapses.