JP5541574B2 - Lubricant coating apparatus, image forming apparatus, process unit, and solid lubricant - Google Patents

Description

  The present invention relates to a lubricant application device for applying lubricant powder obtained by scraping from a solid lubricant to an object to be applied, and an image forming apparatus and a process unit using the same. is there. The present invention also relates to a solid lubricant mounted on the lubricant application device.

  As this type of lubricant application device, for example, the one described in Patent Document 1 is known. This lubricant application device has a solid lubricant, an application brush roller as an application member, and a spring as an urging means for urging the solid lubricant toward the application brush roller. A solid lubricant is pressed against a coating brush roller that rotates while being in contact with a photosensitive member that is a coated body by a spring. The application brush roller applies lubricant powder obtained by scraping from the solid lubricant along with its rotation to the surface of the photoreceptor. The surface of the photoconductor coated with lubricant powder weakens the physical adhesion to the toner, thereby improving the transferability of the toner image to the transfer body, improving the toner cleaning performance, Toner adhesion to the toner is suppressed.

  The solid lubricant gradually decreases in thickness as it is scraped off by the application brush roller. However, the solid lubricant is urged toward the application brush roller by the spring, so that it continues to contact the application brush roller regardless of the thickness. . However, if the thickness is very small, the possibility of generating cracks and chips increases. Therefore, when the thickness is reduced to a certain level, it is necessary to replace the solid lubricant with a new one.

  Therefore, in the lubricant application device described in Patent Document 1, the amount of movement of the solid lubricant in the thickness direction is detected by a sensor disposed so as to face the solid lubricant from the spring side via a gap. ing. Then, when the movement amount reaches a predetermined threshold, that is, when the thickness of the solid lubricant is reduced to a predetermined value, the user is notified of the end of the life of the solid lubricant.

  However, depending on the layout in the apparatus, the amount of movement of the solid lubricant in the thickness direction may be detected because the sensor cannot be disposed at a position facing the solid lubricant in the thickness direction. It can be difficult.

  The present invention has been made in view of the above background, and the object of the present invention is to detect the arrival of the life of the solid lubricant regardless of the amount of movement of the solid lubricant in the thickness direction. It is to provide a lubricant application device and the like.

In order to achieve the above object, the invention of claim 1 is directed to a solid lubricant, an application member for applying a lubricant powder scraped from the solid lubricant to an application body, and a holding for holding the solid lubricant. a lubricant applying device comprising a member, and a biasing means for the solid lubricant on the holding member to bias the holding member abuts on the coating member, the coating member and the solid lubricant A lubricant moving means for moving the solid lubricant in a direction perpendicular to the direction of movement of the coating member surface on the rubbing surface, and the coating member contacts its surface with the solid lubricant and the coated body, respectively. The lubricant powder scraped from the solid lubricant is applied to the object to be coated, and the lubricant moving means reduces the thickness of the solid lubricant. The amount of movement according to Is characterized in that in the direction orthogonal to the applying member surface movement direction of the rubbing surface of the lubricant and the coating member said and moves the solid lubricant.
Also, the invention of claim 2, in the lubricant applying device according to claim 1, a movement amount detecting means for detecting the movement amount in the direction to the perpendicular, the consumption of the solid lubricant on the basis of the detection result of this It is characterized by providing consumption amount grasping means for grasping.
Further, the invention of claim 3 is the lubricant application device of claim 2 , wherein the lubricant moving means moves the solid lubricant in the orthogonal direction by a moving amount larger than a thickness reducing amount. It is characterized by being.
The invention according to claim 4 is the lubricant application device according to claim 2 or 3 , wherein the application member is a rotary shaft member that is rotatably supported, and a plurality of the shafts are erected on a peripheral surface thereof. An application brush roller having a brush roller portion consisting of the raised brush, and the orthogonal direction is the rotation axis direction of the application brush roller.
The invention according to claim 5 is the lubricant application apparatus according to claim 4 , wherein the lubricant moving means has inclinations inclined with respect to the rotation axis direction and the thickness direction of the solid lubricant, respectively. The solid lubricant or holding member that has a guide rail or a guide groove and engages with the guide rail or the guide groove is provided in both the thickness direction and the rotation axis direction as the thickness of the solid lubricant decreases. It moves in the direction along the said guide rail or guide groove containing a component, It is characterized by the above-mentioned.
The invention according to claim 6 is the lubricant application device according to claim 5 , wherein the solid lubricant or the holding member is a concave portion that engages with the guide rail or a convex portion that engages with the guide groove. It is characterized by having.
The invention according to claim 7 is the lubricant application apparatus according to claim 4 , wherein the lubricant moving means has inclinations inclined with respect to the rotation axis direction and the thickness direction of the solid lubricant, respectively. The solid lubricant and the holding member that have a guide rod and are engaged with the guide rod include both components in the thickness direction and the rotation axis direction as the thickness of the solid lubricant decreases. It is moved in the direction along the guide rod.
The invention according to claim 8 is the lubricant application apparatus according to claim 7 , wherein the solid lubricant and the holding member have a hole portion that engages with the guide rod. Is.
The invention of claim 9 is the lubricant application device of claim 4 , wherein the lubricant moving means has inclined surfaces that are inclined with respect to the rotational axis direction and the thickness direction of the solid lubricant, respectively. Then, while abutting one end of the holding member in the rotation axis direction on the inclined surface, the holding member and the solid lubricant are moved in the thickness direction and the rotation axis direction as the thickness of the solid lubricant decreases. It moves in the direction along the said inclined surface containing both components, It is characterized by the above-mentioned.
The invention of claim 1 0, in the lubricant applying device according to claim 5, 6 or 9, wherein the rotation with the solid lubricant in the initial state without consuming, to consume a predetermined thickness of More than the amount moved in the axial direction, the solid lubricant in a state of being consumed near the end of its life is increased in the amount moved in the rotational axis direction as it is consumed by the predetermined thickness. The inclination angle of the guide rail, the guide groove or the inclined surface is changed in at least two stages.
The invention of claim 1 1, a lubricant applying device according to claim 4, wherein the lubricant moving unit has a curved surface, one end of the rotation axis direction of the holding member to the curved surface While abutting, the holding member and the solid lubricant are moved in a direction along the curved surface including the components in both the thickness direction and the rotation axis direction as the thickness of the solid lubricant decreases. It is characterized by being.
The invention of claim 1 2, in the lubricant applying device of claim 1 1, the solid lubricant in the initial state without consuming, the rotation axis direction with to consume a predetermined thickness of The curved surface so that the amount of the solid lubricant in the state of consumption near the end of its life is increased in the rotational axis direction as the predetermined amount is consumed rather than the amount of movement. The curvature of is changed in at least two stages.
The invention of claims 1 to 3, there is provided a lubricant applying device according to claim 4, wherein the solid lubricant, the rotation axis direction of the one end the rotation axis direction a step that the center side thicker than the side And the lubricant moving means directs the solid lubricant toward the abutting member in a state where the one end of the solid lubricant is abutted against the abutting member. It is characterized by being energized.
The invention of claims 1 to 4, in any one of the lubricant applying device according to claim 5 to 1 3, provided the moving force imparting means for imparting a moving force toward the rotation axis direction with respect to the solid lubricant It is characterized by that.
The invention of claim 1 5, in the lubricant applying device according to claim 1 4, wherein the application brush roller, sequence deviation of the brushed, rigid deviation, by flocking density deviation or hair falling habit, the solid lubricant In addition to the force in the endless moving direction on the solid lubricant on the rubbing surface, the force in the rotational axis direction is applied to function as the moving force applying means. Is.
The invention of claims 1 to 6, in any one of the lubricant applying device according to claim 5 to 1 5, as the solid lubricant, the length of the rotation axis direction, of the brush roller portion of the applying brush roller What is used is one that is larger than the length and whose difference in length is equal to or greater than the amount of movement of the solid lubricant in the rotational axis direction from the initial state to the end of the life.
The invention of claim 17 is the lubricant application apparatus of claim 16 , wherein the amount of decrease in thickness from the initial state of the solid lubricant specified based on the grasping result by the consumption grasping means is Prior to reaching the same value as the distance from the outer peripheral surface of the rotating shaft member of the application brush roller to the outer peripheral surface of the brush roller portion, an informing means for informing the end of the life of the solid lubricant is provided. It is a feature.
The invention according to claim 18 is the lubricant application device according to claim 16 or 17 , wherein the solid lubricant has an end side opposite to a moving direction along the rotational axis direction. A taper that approaches the coating brush roller as it goes from the center to the center side is used.
The invention of claim 19, in any one of the lubricant applying device according to claim 5 to 1 5, as the application brush roller, the rotation length of the rotational axis direction of the brush roller portion in the medium to be coated What is larger than the length in the axial direction is used, and the solid lubricant having a length in the rotational axis direction larger than the length in the rotational axis direction of the coated body is used. It is.
The invention of claim 2 0, in any one of the lubricant applying device according to claim 1 to 19, provided with a support member for movably supported along said biasing means to said rotational axis, said solid lubricant The support member is moved in the direction of the rotational axis in conjunction with the movement of the agent and the holding member in the direction of the rotational axis.
The invention of claim 2 1, in any one of the lubricant applying device of claims 1 to 19, as the urging means, by pressing a rotatable cam member to the holding member, the holding member and the solid What urges | biases a lubricant toward the said application | coating member is used.
The invention of claim 2 2, a lubricant applying device according to claim 4, wherein the lubricant moving unit, the axis of rotation, respectively swingable swing arm both ends in the direction of the holding member While supporting, the oscillating arm is urged from one end side to the other end side in the oscillating track so that the holding member and the solid lubricant are in a direction including both components in the thickness direction and the rotation axis direction. It is characterized by being moved.
The invention of claim 2 3, in any one of the lubricant applying device according to claim 2 to 19 or claims 22 to 23,,, the movement detector, the solid lubricant in the direction the orthogonal or It is characterized by being arranged on the side of the holding member.
According to a twenty- fourth aspect of the present invention, there is provided an image carrier that carries a toner image, a toner image forming unit that forms a toner image on the surface thereof, and a lubricant coating that applies a lubricant to the surface of the image carrier. in the image forming apparatus and means, as the lubricant application means, it is characterized in that using any of the lubricant applying device according to claim 1 or 2 3.
According to a twenty- fifth aspect of the present invention, there is provided an image carrier that carries a toner image, a lubricant application device that applies a lubricant to the surface of the image carrier, and toner image formation that forms a toner image on the surface of the image carrier. And at least the image carrier and the lubricant applicator are held by a common holder so that they can be integrally attached to and detached from the image forming apparatus main body as a single unit. a configuration and process units, the lubricant applying device is characterized in that it is one of the lubricant applying device according to claim 1 or 2 3.
Further, the invention of claim 26 is an application member that applies lubricant powder scraped from the solid lubricant to the coated body as it rotates while contacting the solid lubricant and the coated body. And a holding member that holds the solid lubricant, and a biasing unit that biases the holding member to bring the solid lubricant on the holding member into contact with the coating member. The solid lubricant is provided with the concave portion corresponding to the guide rail portion or the convex portion corresponding to the guide groove in the lubricant application device according to claim 6 , or 8 is provided with the hole corresponding to the guide rod in the lubricant applying device.

  In these inventions, in the process of reducing the thickness of the solid lubricant by consumption, the amount corresponding to the amount of the reduction is in a direction orthogonal to the surface movement direction of the coating member on the rubbing surface with the coating member. Moving. Therefore, by grasping the consumption amount of the solid lubricant based on the amount of movement, it is possible to detect the end of the life of the solid lubricant regardless of the amount of movement of the solid lubricant in the thickness direction.

1 is a schematic configuration diagram illustrating a printer according to an embodiment. FIG. 2 is an enlarged configuration diagram illustrating a Y process unit and a developing device in the printer. FIG. 3 is a perspective view showing the process unit and the developing device. FIG. 2 is a perspective view showing the developing device. FIG. 3 is an enlarged configuration diagram showing the process unit together with an intermediate transfer belt. The assembly exploded perspective view showing the process unit. The disassembled perspective view which shows the inside of the lubricant coating device of the process unit. The expanded partial perspective view which shows the inside of the same lubricant application device partially. The schematic diagram for demonstrating the motion of the solid lubricant on the guide rail of the lubricant application device. The graph which shows an example of the relationship between the thickness consumption of a solid lubricant, and the movement amount to a brush rotation axis direction. The side view which shows the solid lubricant of the initial state in the lubricant coating device, and its surrounding structure. The side view which shows the solid lubricant of the state consumed until the lifetime, and its surrounding structure. The perspective view which shows the flocked brush sheet | seat used for the brush roller part of the application brush roller in the same lubricant application device. The perspective view which shows the one end part of the axial direction of the application brush roller with a solid lubricant. The perspective view which shows the whole area of the rotating shaft direction of the application brush roller with a solid lubricant. The schematic diagram for demonstrating the relationship between the application brush roller and various directions. Sectional drawing for demonstrating the motion of the solid lubricant on a guide rail. The side view which shows the solid lubricant of the initial state in the printer which concerns on a 1st modification, and its surrounding structure. The side view which shows the solid lubricant of the state consumed until the lifetime, and its surrounding structure. The expanded partial perspective view which shows partially the inside of the lubricant application apparatus for Y in the printer which concerns on a 2nd modification. The expansion partial perspective view which shows partially the inside of the lubricant application apparatus for Y in the printer which concerns on a 3rd modification. The expanded partial perspective view which shows partially the inside of the lubricant application apparatus for Y in the printer which concerns on a 4th modification. The expansion partial perspective view which shows partially the inside of the lubricant application apparatus for Y in the printer which concerns on a 5th modification. The expanded partial perspective view which shows partially the inside of the lubricant application apparatus for Y in the printer which concerns on a 6th modification. The enlarged partial perspective view which shows partially the inside of the lubricant application apparatus for Y in the printer which concerns on a 7th modification. The expanded partial perspective view which shows partially the inside of the lubricant application apparatus for Y in the printer which concerns on an 8th modification. The partial expansion perspective view which shows the one end part of the application | coating brush roller for Y in the printer which concerns on a 9th modification. The perspective view which shows the flocked brush sheet | seat used for the application | coating brush roller for Y in the printer which concerns on a 10th modification. The perspective view which shows the flocked brush sheet | seat used for the application | coating brush roller for Y in the printer which concerns on an 11th modification. The side view which shows the application | coating brush roller for Y, the solid lubricant, and the holding member in the printer which concerns on a 12th modification. The side view which shows the same solid lubricant at the time of life end, and its surrounding structure. The side view which shows the solid lubricant for Y in the printer which concerns on a 13th modification with the surrounding structure. The side view which shows the solid lubricant at the time of reaching | attaining a lifetime with the surrounding structure. The side view which shows solid lubricant 10Y for Y in the printer which concerns on a 14th modification with the surrounding structure. The side view which shows the solid lubricant at the time of reaching | attaining a lifetime with the surrounding structure. The side view for demonstrating the curve of the coil spring accompanying the movement to the brush axial direction of a holding member. The partial expansion perspective view which shows the holding member of the printer which concerns on a 15th modification with the surrounding structure. The expanded block diagram which shows the urging | biasing mechanism for Y in the printer which concerns on a 16th modification. The side view and front view which show the application | coating brush roller for Y of the printer which concerns on a 17th modification with the surrounding structure. The side view and front view which show the solid lubricant at the time of reaching | attaining lifetime with the surrounding structure. The expansion block diagram which shows the taper provided in the inside of the casing in the lubricant application apparatus for Y of the printer which concerns on an 18th modification with the edge part of a solid lubricant. The expanded block diagram which shows the taper provided in the inside of the casing in the lubricant application apparatus for Y of the printer which concerns on a 19th modification with the edge part of a solid lubricant. The expanded block diagram which shows the edge part of the solid lubricant at the time of reaching | attaining a lifetime with the surrounding structure. The expansion block diagram which shows the bending member provided in the inside of the casing in the lubricant application apparatus for Y of the printer which concerns on a 20th modification with the edge part of a solid lubricant. The expanded block diagram which shows the bending member provided in the inside of the casing in the lubricant application apparatus for Y of the printer which concerns on a 21st modification with the edge part of a solid lubricant. The side view and front view which show the solid lubricant of the initial state in the printer which concerns on a 22nd modification with the surrounding structure. The side view and front view which show the solid lubricant with the surrounding structure at the time of a lifetime having come. The side view which shows the solid lubricant of the initial state in the printer which concerns on a 23rd modification with the surrounding structure. The side view which shows the solid lubricant at the time of the end of a life with the surrounding structure.

Hereinafter, as an image forming apparatus to which the present invention is applied, an embodiment of an electrophotographic printer (hereinafter simply referred to as a printer) will be described.
First, a basic configuration of the printer according to the present embodiment will be described. FIG. 1 is a schematic configuration diagram illustrating a printer according to an embodiment. This printer includes four image forming units 1Y, C, M, and K for yellow, magenta, cyan, and black (hereinafter referred to as Y, C, M, and K) as image forming units as toner image forming means. ing. These use Y, C, M, and K toners of different colors as image forming substances for forming an image, but the other configurations are the same. Taking an image forming unit 1Y for generating a Y toner image as an example, this has a process unit 2Y and a developing unit 25Y as shown in FIG. As shown in FIG. 3, these units are integrally attached to and detached from the printer main body as an image forming unit 1Y. In a state where it is detached from the printer main body, as shown in FIG. 4, the developing unit 25Y can be attached to and detached from a process unit (2Y in FIG. 3) not shown.

  In FIG. 2 described above, the process unit 2Y includes a drum-shaped photosensitive member 3Y as a latent image carrier, a drum cleaning device 4Y, a static eliminator (not shown), a charging device 20Y, and the like.

  The charging device 20Y uniformly charges the surface of the photoreceptor 3Y that is driven to rotate in the clockwise direction in the drawing by a driving unit (not shown). In the figure, a method of uniformly charging the photosensitive member 3Y by contacting or approaching the photosensitive member 3Y with a charging roller 21Y driven to rotate counterclockwise in the drawing while a charging bias is applied by a power source (not shown). The charging device 20Y is shown. Instead of the charging roller 21Y, a roller that contacts or approaches a charging brush may be used. In addition, a charger that uniformly charges the photoreceptor 3Y by a charger method, such as a scorotron charger or a corotron charger, may be used. However, since the scorotron charger system generates ozone during discharge, it has not been used much in recent years from the viewpoint of placing importance on the environment. In addition, the corotron charger system generates less ozone but charges the photoreceptor positively, so it has not been used much in recent years when the inversion phenomenon system has become mainstream. In recent years, the charging roller method is the most common method. The charging roller system includes a contact charging roller system in which the charging roller is brought into contact with the photoconductor and a non-contact charging roller system in which the charging roller is brought into contact with the photoconductor in a non-contact manner.

  In the contact charging roller method, when a charging bias applied to the charging roller is obtained by superimposing an alternating current on a direct current, a higher image quality can be obtained than when a structure consisting only of a direct current is employed. On the other hand, there is a demerit that it is easy to generate so-called filming for fixing the toner to the photosensitive member. In addition, in the case of the superimposed bias, there is a merit that the charged potential on the surface of the photosensitive member can be stabilized by controlling the alternating current at a constant current, regardless of the fluctuation of the resistance value of the charging roller due to the environmental change. There are disadvantages in that the cost of the high-voltage power supply increases and the AC high-frequency sound is noisy. When a charging bias consisting of only a direct current is employed, it becomes easy to change the charging potential due to fluctuations in the resistance value of the charging roller due to changes in the environment, so a measure to change the voltage value with changes in the environment is required.

  On the other hand, in the non-contact charging roller system, if an AC voltage is used as the charging bias and constant current control is performed, unevenness in the charging potential is likely to occur due to gap fluctuation between the photosensitive member and the charging roller. It is necessary to change the voltage value. However, since it is a non-contact method, there is a margin for contamination of the charging roller than the contact method. As a method of changing the AC voltage, a method of switching the voltage value according to the result of detecting the temperature in the vicinity of the charging roller, a method of switching the voltage value according to the result of periodically detecting ground contamination on the photosensitive member, feedback For example, a method of determining an applied voltage based on a current value may be used. By adopting these methods, the surface potential of the photoreceptor is charged to about −500V to −700V.

  As a method for driving the charging roller, there are a method in which the photosensitive member is pressed against the photosensitive member and driven by a frictional force, a method in which a driving force is obtained from a photosensitive member gear, and the like. In the case of a low speed machine, the former method is often used, but in the machine that requires high speed and high image quality, the latter method is often used.

  In FIG. 2, when the surface of the charging roller 21Y is contaminated with toner, the charging ability at the contaminated portion is lowered, and it becomes difficult to charge the photoreceptor 3Y to a target potential. Therefore, the charging roller 21Y is in contact with a cleaning roller 22Y for removing the toner adhering to the surface. As the cleaning roller 22Y, a flocking roller in which fibers are electrostatically flocked on a rotating shaft member that is rotatably supported, a melamine roller in which a melamine resin is arranged on the roller around the rotating shaft member, and the like can be used. From the viewpoint of extending the life, the melamine roller is advantageous. If slip occurs between the cleaning roller 22Y and the charging roller 21Y, the toner is rubbed against the surface of the charging roller 21Y and filming is likely to occur. More preferably, the cleaning roller 22Y is driven by the charging roller 21Y as a driven roller.

  The surface of the photoreceptor 3Y uniformly charged by the charging device 20Y is exposed and scanned by a laser beam emitted from an optical writing unit to be described later, and carries a Y electrostatic latent image.

  The developing unit 25Y as developing means has a first agent accommodating portion 26Y in which a first conveying screw 28Y is disposed. Further, it also has a second agent storage portion 27Y in which a toner concentration sensor (hereinafter referred to as a toner concentration sensor) 29Y including a magnetic permeability sensor, a second transport screw 30Y, a developing roll 31Y, a doctor blade 34Y, and the like are disposed. . In these two agent storage portions, a Y developer (not shown) composed of a magnetic carrier and a negatively chargeable Y toner is included. The first transport screw 28Y is driven to rotate by a driving unit (not shown), so that the Y developer in the first agent storage unit 26Y is transported from the near side to the far side in the direction perpendicular to the drawing sheet. And it penetrates into the 2nd agent accommodating part 27Y through the communication port which is not illustrated provided in the partition wall between the 1st agent accommodating part 26Y and the 2nd agent accommodating part 27Y.

  The second transport screw 30Y in the second agent container 27Y is driven to rotate by a driving unit (not shown), thereby transporting the Y developer from the back side to the front side in the drawing. The Y developer during conveyance is detected by a toner concentration sensor 29Y fixed to the bottom of the first agent storage unit 27Y. In this way, the developing roll 31Y is arranged in a posture parallel to the second transport screw 30Y above the second transport screw 30Y that transports the Y developer. The developing roll 31Y includes a magnet roller 33Y in a developing sleeve 32Y made of a non-magnetic pipe that is driven to rotate counterclockwise in the drawing. A part of the Y developer conveyed by the second conveying screw 30Y is pumped up to the surface of the developing sleeve 32Y by the magnetic force generated by the magnet roller 33Y. Then, after the layer thickness is regulated by a doctor blade 34Y arranged so as to maintain a predetermined gap from the developing sleeve 32Y as a developing member, the layer thickness is regulated and conveyed to a developing area facing the photosensitive member 3Y. Y toner is adhered to the Y electrostatic latent image. This adhesion forms a Y toner image on the photoreceptor 3Y. The Y developer that has consumed the Y toner by the development is returned to the second conveying screw 30Y as the developing sleeve 32Y of the developing roll 31Y rotates. And if it conveys to the near end in a figure, it will return in the 1st agent accommodating part 28Y through the communication port which is not shown in figure.

  The result of detecting the magnetic permeability of the Y developer by the toner concentration sensor 29Y is sent as a voltage signal to a control unit (not shown). Since the magnetic permeability of the Y developer has a correlation with the Y toner concentration of the Y developer, the toner concentration sensor 29 outputs a voltage having a value corresponding to the Y toner concentration. The control unit includes a RAM, in which a Y Vtref which is a target value of the output voltage from the toner density sensor 29Y and a C, M, K toner density sensor mounted on another developing unit. The data of C Vtref, M Vtref, and K Vtref, which are target values of the output voltage, are stored. For the Y developing unit 25Y, the value of the output voltage from the toner density sensor 29Y is compared with the Y Vtref, and a Y toner supply device (not shown) is driven for a time corresponding to the comparison result. With this driving, an appropriate amount of Y toner is supplied to the Y developer whose Y toner density has been reduced by the consumption of Y toner accompanying development in the first agent container 26Y. For this reason, the Y toner concentration of the Y developer in the second agent container 27Y is maintained within a predetermined range. Similar toner supply control is performed for the developers in the process units (1C, M, K) for other colors.

  The Y toner image formed on the photoreceptor 3Y is intermediately transferred to an intermediate transfer belt described later. The drum cleaning device 4Y of the process unit 2Y removes the toner remaining on the surface of the photoreceptor 3Y after the intermediate transfer process. As a result, the surface of the photoreceptor 3Y that has been subjected to the cleaning process is neutralized by a neutralizing device (not shown). By this charge removal, the surface of the photoreceptor 3Y is initialized and prepared for the next image formation.

  In FIG. 1 described above, in the image forming units 1C, M, and K for other colors, C, M, and K toner images are similarly formed on the photoreceptors 3C, M, and K, and the intermediate transfer belt 61 is formed. It is superimposed and transferred on top.

  An optical writing unit 40 is disposed below the image forming units 1Y, 1C, 1M, and 1K in the drawing. The optical writing unit 40 serving as a latent image forming unit irradiates the photoconductors 3Y, C, M, and K of the image forming units 1Y, 1C, 1M, and 1K with a laser beam L emitted based on the image information. Thereby, electrostatic latent images for Y, C, M, and K are formed on the photoreceptors 3Y, 3C, 3M, and 3K. The optical writing unit 40 deflects the laser light L emitted from the light source by the polygon mirror 41 that is rotationally driven by a motor, and passes through the photoreceptors 3Y, 3C, 3M, and 3K via a plurality of optical lenses and mirrors. Is irradiated. In place of such a configuration, an optical scanning device using an LDE array may be employed.

  A first paper feed cassette 51 and a second paper feed cassette 52 are arranged below the optical writing unit 40 so as to overlap in the vertical direction. In each of these paper feed cassettes, a plurality of recording papers P as recording members are accommodated in a stack of recording papers. The uppermost recording paper P includes a first paper feed roller 51a, The second paper feed rollers 52a are in contact with each other. When the first paper feed roller 51a is driven to rotate counterclockwise in the figure by driving means (not shown), the uppermost recording paper P in the first paper feed cassette 31 is vertically oriented on the right side of the cassette in the figure. The paper is discharged toward a paper feed path 53 disposed so as to extend. Further, when the second paper feed roller 52 a is driven to rotate counterclockwise in the drawing by a driving means (not shown), the uppermost recording paper P in the second paper feed cassette 52 is directed toward the paper feed path 53. Discharged.

  A plurality of transport roller pairs 54 are disposed in the paper feed path 53, and the recording paper P fed into the paper feed path 53 is sandwiched between the rollers of the transport roller pair 54 while being fed between the paper feed paths 53. 53 is conveyed from the lower side to the upper side in the figure.

  A registration roller pair 55 is disposed at the end of the paper feed path 53. The registration roller pair 55 temporarily stops the rotation of both rollers as soon as the recording paper P fed from the conveying roller pair 54 is sandwiched between the rollers. Then, the recording paper P is sent out toward a later-described secondary transfer nip at an appropriate timing.

  Above the image forming units 1Y, 1C, 1M, and 1K, a transfer unit 60 that is endlessly moved counterclockwise in the drawing while an intermediate transfer belt 61 that is an endless moving body is stretched is disposed. The transfer unit 60 serving as a transfer unit includes an intermediate transfer belt 61, a belt cleaning unit 62, a first bracket 63, a second bracket 64, and the like. Also provided are four primary transfer rollers 65Y, 65C, 65M, 65K, a secondary transfer backup roller 66, a drive roller 67, an auxiliary roller 68, a tension roller 69, and the like. The intermediate transfer belt 61 is endlessly moved counterclockwise in the figure by the rotational driving of the driving roller 67 while being stretched around these eight rollers. The four primary transfer rollers 65Y, 65C, 65M, 65K sandwich the intermediate transfer belt 61 moved endlessly in this manner from the photoreceptors 3Y, 3C, 3M, and 3K to form primary transfer nips. ing. Then, a transfer bias having a polarity opposite to that of the toner (for example, plus) is applied to the back surface (loop inner peripheral surface) of the intermediate transfer belt 61. The intermediate transfer belt 61 sequentially passes through the primary transfer nips for Y, C, M, and K along with the endless movement thereof, and on the photoreceptor 3Y, C, M, and K on the front surface. The Y, C, M, and K toner images are superimposed and primarily transferred. As a result, a four-color superimposed toner image (hereinafter referred to as a four-color toner image) is formed on the intermediate transfer belt 61.

  The secondary transfer backup roller 66 sandwiches the intermediate transfer belt 61 with the secondary transfer roller 70 disposed outside the loop of the intermediate transfer belt 61 to form a secondary transfer nip. The registration roller pair 55 described above feeds the recording paper P sandwiched between the rollers toward the secondary transfer nip at a timing at which the recording paper P can be synchronized with the four-color toner image on the intermediate transfer belt 61. The four-color toner image on the intermediate transfer belt 61 is affected by the secondary transfer electric field formed between the secondary transfer roller 70 to which the secondary transfer bias is applied and the secondary transfer backup roller 66, and the influence of the nip pressure. The secondary transfer is batch-transferred onto the recording paper P in the secondary transfer nip. Then, combined with the white color of the recording paper P, a full color toner image is obtained.

  Untransferred toner that has not been transferred to the recording paper P adheres to the intermediate transfer belt 61 after passing through the secondary transfer nip. This is cleaned by the belt cleaning unit 62. The belt cleaning unit 62 has a cleaning blade 62a in contact with the front surface of the intermediate transfer belt 61, thereby scraping off and removing the transfer residual toner on the belt.

  The first bracket 63 of the transfer unit 60 swings at a predetermined rotation angle about the rotation axis of the auxiliary roller 68 as the solenoid (not shown) is turned on / off. When forming a monochrome image, the printer according to the embodiment rotates the first bracket 63 slightly in the counterclockwise direction in the drawing by driving the solenoid described above. This rotation causes the Y, C, and M primary transfer rollers 65Y, C, and M to revolve counterclockwise in the drawing about the rotation axis of the auxiliary roller 68, thereby causing the intermediate transfer belt 61 to move in the Y, C, and C directions. , M is separated from the photoconductors 3Y, 3C, 3M. Of the four image forming units 1Y, 1C, 1M, and 1K, only the K image forming unit 1K is driven to form a monochrome image. Accordingly, it is possible to avoid wear of the image forming units due to unnecessary driving of the Y, C, and M image forming units when forming a monochrome image.

  A fixing unit 80 is disposed above the secondary transfer nip in the drawing. The fixing unit 80 includes a pressure heating roller 81 that contains a heat source such as a halogen lamp, and a fixing belt unit 82. The fixing belt unit 82 includes a fixing belt 84 as a fixing member, a heating roller 83 containing a heat source such as a halogen lamp, a tension roller 85, a driving roller 86, a temperature sensor (not shown), and the like. Then, the endless fixing belt 84 is endlessly moved in the counterclockwise direction in the drawing while being stretched by the heating roller 83, the tension roller 85, and the driving roller 86. In the process of endless movement, the fixing belt 84 is heated from the back side by the heating roller 83. A pressure heating roller 81 that is driven to rotate in the clockwise direction in the drawing is in contact with the surface of the fixing belt 84 that is heated in this manner from the front side. Thus, a fixing nip where the pressure heating roller 81 and the fixing belt 84 abut is formed.

  A temperature sensor (not shown) is disposed outside the loop of the fixing belt 84 so as to face the front surface of the fixing belt 84 with a predetermined gap, and the fixing belt 84 just before entering the fixing nip. Detect surface temperature. This detection result is sent to a fixing power supply circuit (not shown). The fixing power supply circuit performs on / off control of power supply to the heat generation source included in the heating roller 83 and the heat generation source included in the pressure heating roller 81 based on the detection result of the temperature sensor. Accordingly, the surface temperature of the fixing belt 84 is maintained at about 140 [°].

  The recording paper P that has passed through the secondary transfer nip is separated from the intermediate transfer belt 61 and then fed into the fixing unit 80. Then, in the process of being conveyed from the lower side to the upper side in the figure while being sandwiched by the fixing nip in the fixing unit 80, the full-color toner image is fixed by being heated or pressed by the fixing belt 84.

  The recording sheet P subjected to the fixing process in this manner is discharged outside the apparatus after passing between the rollers of the discharge roller pair 87. A stack unit 88 is formed on the top surface of the printer body, and the recording paper P discharged to the outside by the discharge roller pair 87 is sequentially stacked on the stack unit 88.

  Above the transfer unit 60, four toner cartridges 100Y, 100C, M, and K that store Y, C, M, and K toners are disposed. The Y, C, M, and K toners in the toner cartridges 100Y, 100C, 100M, and 100K are appropriately supplied to the developing units 25Y, 25C, 25M, and 25K of the image forming units 1Y, 1C, 1M, and 1K. The toner cartridges 100Y, 100C, 100M, and 100K are detachable from the printer main body independently of the image forming units 1Y, 1C, 1M, and 1K.

  FIG. 5 is an enlarged configuration diagram showing the Y process unit 2 </ b> Y together with the intermediate transfer belt 61. FIG. 6 is an exploded perspective view showing the process unit 2Y. FIG. 7 is an exploded perspective view showing the inside of the lubricant application device 6Y of the process unit 2Y. In these drawings, residual toner that has not been transferred to the intermediate transfer belt 61 is attached to the surface of the photoreceptor 3Y after passing through the primary transfer nip for Y in contact with the intermediate transfer belt 61. This transfer residual toner is removed by the drum cleaning device 4Y of the process unit 2Y.

  In the drum cleaning device 4Y, the free end side of the cleaning blade 5Y that is cantilevered is brought into contact with the surface of the photoreceptor 3Y in the counter direction, and the transfer residual toner is scraped off from the surface of the photoreceptor 3Y by the blade edge. The residual toner that has been scraped off falls onto a collecting coil in the drum cleaning device 4Y and is discharged out of the drum cleaning device 4Y. The discharged transfer residual toner falls into a waste toner bottle (not shown).

  The surface of the photoreceptor 3Y after the cleaning process by the drum cleaning device 4Y is subjected to the lubricant application process and the lubricant leveling process by the lubricant application device 6Y. The lubricant application device 6Y has a brush tip of an application brush roller 7Y that includes a rotary shaft member 8Y that is rotatably supported and a brush roller portion 9Y that includes a plurality of raised brushes that are erected on the peripheral surface thereof. It is rotated in the clockwise direction in the figure while being brought into contact with the photoreceptor 3Y. A solid lubricant 10Y urged toward the application brush roller 7Y is pressed against the application brush roller 7Y together with the holding member 17Y by the coil spring 19Y. The application brush roller 7 </ b> Y applies lubricant powder obtained by scraping from the solid lubricant 10 </ b> Y to the surface of the photoreceptor 3 </ b> Y as it is rotationally driven. As a result, the surface frictional resistance of the photoreceptor 3Y is reduced to improve the cleaning property, the transfer property, and the suppression of filming.

  As raising | lifting used for the brush roller part 9Y of the application brush roller 7Y which is an application | coating member, what consists of an insulating or electroconductive polyethylene terephthalate, an acrylic fiber, etc. can be illustrated. Instead of the application brush roller 7Y, an application sponge roller having a sponge roller portion may be used.

  As solid lubricant 10Y, what consists of various fatty acid salts and what consists of zinc stearate can be illustrated. Other examples include fatty acids such as stearic acid, palmitic acid, myristic acid, oleic acid, and fatty acid metal salts composed of metals such as zinc, aluminum, calcium, magnesium, iron, and lithium as main components. You can also. In particular, zinc stearate is suitable.

Next, a characteristic configuration of the printer according to the embodiment will be described.
FIG. 8 is an enlarged partial perspective view partially showing the inside of the Y lubricant application device. In the figure, the solid lubricant 10Y is fixed to the surface of a holding member 17Y made of C-type steel by a double-sided tape or the like. A coil spring 19Y is pressed against the back surface of the lubricant fixing surface of the holding member 17Y. The coil spring 19Y urges the solid lubricant 10Y in the direction of arrow A in the drawing toward the application brush roller (not shown) via the holding member 17Y. This arrow A direction is a direction along an orthogonal virtual plane orthogonal to the rotation axis direction of the application brush roller 7Y and toward the center of the application brush roller 7Y.

  The solid lubricant 10Y is formed into an elongated block shape so as to contact almost the entire region in the longitudinal direction of the brush roller portion of the application brush roller 7Y. The width that is the dimension in the short direction of the block-shaped solid lubricant 10Y is set to a value larger than the width of the holding member 17Y. For this reason, the solid lubricant 10Y protrudes in the width direction from the holding member 17Y on the surface of the holding member 17Y. A slanted groove-like recess 11Y is formed on the side surface of the protruding lubricant portion. There are two side surfaces in the width direction, and concave portions 11Y are formed on the respective side surfaces. Moreover, in one side surface, the recessed part 11Y is each provided in the both ends of the lubricant longitudinal direction which is a direction along a brush rotating shaft direction.

  On the other hand, two inclined guide rails GL are formed on each of the two inner walls Sa1 and Sa2 facing the recess 11Y of the solid lubricant 10Y among the plurality of inner walls in the casing of the lubricant application device. The solid lubricant 10Y is set in such a posture that the recess 11Y as its engaging portion is engaged with the guide rail GL.

  FIG. 9 is a schematic diagram for explaining the movement of the solid lubricant 10Y on the guide rail GL. In the same figure, arrow B1 direction has shown the direction which goes to the other end side from the brush one end side among the directions along the rotating shaft direction of the application | coating brush roller which is not shown in figure. When the holding member (not shown) is urged by the coil spring in the direction of arrow A in the figure, the solid lubricant 10Y tends to move in the direction of arrow A in the figure. Then, the inner surface of the recess 11Y of the solid lubricant 10Y comes into contact with the side surface of the guide rail GL. This side surface extends in the arrow E direction including both components of the arrow A direction along the lubricant thickness direction and the arrow B1 direction along the brush rotation axis direction. When the inner surface of the recess 11Y comes into contact with the side surface of the guide rail GL, the force of the solid lubricant 10Y going to the arrow A direction is converted into the force in the arrow E direction along the guide rail GL. The solid lubricant 10Y moves along the guide rail GL having an inclination in the direction of arrow E, thereby moving in the direction of arrow B1 while moving in the direction of arrow A.

  In the same figure, the location of the level of the bottom surface of the solid lubricant 10Y in the extending direction of the guide rail GL is determined by the thickness of the solid lubricant 10Y. When the thickness of the solid lubricant 10Y is relatively thick, the bottom surface level of the solid lubricant 10Y is located at a location relatively distant from an application brush roller (not shown). The position is in the vicinity of the lower end of the rail in FIG. As the thickness of the solid lubricant 10Y decreases, the bottom surface level of the solid lubricant 10Y approaches toward the application brush roller. In the figure, the bottom level gradually increases. That is, as the thickness of the solid lubricant 10Y decreases, the bottom surface level of the solid lubricant 10Y gradually moves in the direction of arrow E. Further, as the solid lubricant 10Y moves in the direction of arrow E, the solid lubricant 10Y also moves in the direction of arrow B1. A correlation is established between the amount of movement in the direction of arrow B1 and the amount of solid lubricant consumed (thickness consumption). For example, when the guide rail GL is tilted 45 [°] with respect to the direction of the arrow A and the direction of the arrow B1, as shown in FIG. 10, the consumption amount of the solid lubricant 10Y, the solid lubricant 10Y and the holding member The amount of movement in the arrow B1 direction is the same.

  In the present embodiment, in the triangle formed by the vector in the arrow A direction, the vector in the arrow B1 direction, and the vector in the arrow E direction in FIG. 9, the side in the arrow B1 direction is made larger than the side in the arrow A direction. Thus, the inclination angle of the guide rail GL is set. Therefore, the amount of movement of the solid lubricant 10Y in the direction of the arrow B1 when the thickness of the solid lubricant 10Y decreases by, for example, 1 [mm] is made larger than 1 [mm]. In such a configuration, the amount of movement of the solid lubricant 10Y in the direction of the arrow B1 is larger than the amount of decrease in the thickness of the solid lubricant 10Y. Then, as will be described later, the consumption amount of the solid lubricant 10Y is grasped based on the movement amount in the arrow B1 direction. By detecting the amount of movement in the arrow B1 direction that is larger than the thickness decrease, the decrease in thickness is amplified and detected, so that the decrease in thickness can be detected with high sensitivity.

  FIG. 11 is a side view showing the solid lubricant 10Y in the initial state and the surrounding configuration. As shown in the figure, as the solid lubricant 10Y and the holding member 17Y, those having a length in the longitudinal direction larger than the length in the rotation axis direction of the brush roller portion 9Y of the application brush roller 7Y are used. As shown in the drawing, the solid lubricant 10Y in the initial state is set in the apparatus so that the end opposite to the arrow B1 direction is positioned outside the end of the brush roller portion 9Y. In this state, the new article detection first electrode 151 and the new article detection second electrode 152 fixed in the apparatus are brought into contact with each other by contacting the metal holding member 17Y. A CPU (Central Processing Unit) (not shown) detects that the new solid lubricant 10Y is set by detecting the conduction. In the drawing, only one electrode for detecting a new article is shown, but this is because the first electrode for detecting new article 151 and the second electrode for detecting new article 152 are perpendicular to each other in the drawing. This is because they are lined up through a predetermined gap.

  When the solid lubricant 10Y in the new state shown in FIG. 11 is scraped off by the application brush roller 7Y and its thickness is gradually reduced, the solid lubricant 10Y and the holding member 17Y are moved along the arrow B1 in the drawing. Move gradually in the direction. Then, the holding member 17Y moves away from the new article detection first electrode 151 and the new article detection second electrode 152 shown in the drawing.

  FIG. 12 is a side view showing the solid lubricant 10Y in a state of being consumed until the end of its life and the surrounding configuration. As shown in the figure, when the thickness of the solid lubricant 10Y decreases to the end of its life, the end of the holding member 17Y in the direction of the arrow B1 comes into contact with the first electrode for life detection 153 and the second electrode for life detection 154. Thereby, the first electrode for life detection 153 and the second electrode for life detection 154 are conducted through the holding member 17Y. The CPU (not shown) detects that the solid lubricant 10Y has been consumed until the end of its life by detecting the conduction. Then, a message for notifying the user of the end of the life is displayed on the display.

  In the above configuration, the first electrode 151 for new article detection, the second electrode for new article detection 152, the first electrode for life detection 153, the second electrode for life detection 154, and the CPU are connected to the solid lubricant 10Y and the holding member 17Y. It functions as movement amount detection means for detecting the movement amount in the direction of arrow B1. Further, the CPU functions as consumption amount grasping means for grasping the consumption amount of the solid lubricant 10Y based on the detection result of the movement amount. Also, the coil spring 19Y, the guide rail GL, and the like are lubricant moving means for moving the solid lubricant 10Y in the brush rotation axis direction, which is a direction orthogonal to the application member surface moving direction, with a movement amount corresponding to the thickness reduction amount. Is functioning as

  In this printer, the application brush roller 7Y actively applies a force in the direction of the rotation axis on the rubbing surface to the solid lubricant 10Y, and the solid lubricant 10Y is pressed by using the force. And the movement in the direction of the arrow B1 is favorably performed.

  FIG. 13 is a perspective view showing a flocked brush sheet 9cY used in the brush roller portion of the application brush roller 7Y. The planted brush sheet 9cY is obtained by planting a plurality of raised brushes 9aY on a rectangular woven fabric 9bY by a known technique.

  FIG. 14 is a perspective view showing one end portion of the application brush roller 7Y in the axial direction together with the solid lubricant 10Y. The application brush roller 7Y includes a metal rotation shaft member 8Y and a brush roller portion 9Y that rotates about the rotation shaft member 8Y. The brush roller portion 9Y includes a roller portion 9dY and a flocked brush sheet 9cY wound spirally around the roller portion 9dY. As shown in the figure, a slight gap G is provided between the spirally wound sheets so that the rectangular flocked brush sheet 9cY follows the peripheral surface of the roller-shaped roller portion 9dY. By providing such a gap G, as shown by an arrow B1 in FIG. 15, the application brush roller 7Y applies a force from one end side to the other end side in the rotation axis direction to the solid lubricant 10Y. It is like that.

  FIG. 16 is a schematic diagram for explaining the relationship between the application brush roller 7Y and various directions. In the same figure, the arrow X direction is the same as the arrow X direction in FIG. 13, and has shown the longitudinal direction in the flocked brush sheet | seat (9cY). Moreover, the arrow Y direction in FIG. 16 is the same as the arrow Y direction in FIG. 13, and has shown the transversal direction in the flocked brush sheet (9cY). In FIG. 16, the arrow Z direction indicates the direction in which the application brush roller 7Y advances on the rubbing surface where the application brush roller 7Y and the solid lubricant rub. In the case of a normal application brush roller, a force mainly in the direction of arrow Z is applied to the solid lubricant from the application brush roller. In addition, in the application brush roller 7Y in which the flocked brush sheet (9cY) is spirally wound, as shown by an arrow D in the drawing, a force in a direction substantially orthogonal to the extending direction of the spiral gap G is applied. It is applied to the solid lubricant from the brush roller 7Y. The direction of arrow D is a direction in which the resultant force of the force traveling in the direction of arrow Z and the force traveling in the direction of arrow C orthogonal thereto is advanced. For this reason, in addition to the force in the arrow Z direction, a force in the arrow B1 direction is applied to the solid lubricant on the rubbing surface with the application brush roller 7Y. As shown in FIG. The lubricant 10Y tries to move in the direction of the arrow B1 along the brush rotation axis direction. In such a configuration, the application brush roller 7Y also functions as a moving force applying unit that applies a moving force in the brush rotation axis direction to the solid lubricant 10Y together with the coil spring 19Y and the like.

  The state previously shown in FIG. 9 shows the movement of the convex portion 18Y of the holding member when a coating brush roller (not shown) is not rotating. When the application brush roller is not rotating, the inner surface of the recess 11Y of the solid lubricant 10Y trying to move in the direction of arrow A as shown in the drawing is in contact with the side surface of the guide rail GL, and the force in the direction of arrow A is applied to the side surface. In the direction of arrow E along At this time, the movement of the solid lubricant 10Y in the direction of arrow E is hindered by the friction between the rail side surface and the concave portion inner surface.

  As shown in FIG. 15, when the application brush roller 7Y rotates, a force in the direction of arrow B1 is applied from the application brush roller 7Y to the solid lubricant 10Y. Then, as shown in FIG. 17, the inner surface of the recess 11Y that has been in contact with one rail side surface of the guide rail GL in the stopped state is separated from the rail side surface. Immediately before the separation, the movement in the direction of arrow E, which has been hindered by the friction with the rail side surface, is promoted, and the solid lubricant 10Y moves smoothly along the direction of arrow E. And it contacts the rail side wall opposite to the rail side surface that has been in contact so far, and is pressed in the direction of arrow E. At this time, the solid lubricant 10Y is pressed against the application brush roller in the direction of arrow E by the force in the direction of arrow B1 by the brush in addition to the force in the direction of arrow A due to the urging of the coil spring. Thereby, generation | occurrence | production of the press defect of solid lubricant 10Y can be suppressed.

  In addition, although the example which provided two recessed parts 11Y with respect to one side surface of solid lubricant 10Y was demonstrated, you may provide three or more.

Next, modifications of the printer according to the embodiment will be described. Unless otherwise specified, the configuration of the printer according to each modification is the same as that of the embodiment.
[First Modification]
FIG. 18 is a side view showing the solid lubricant 10Y in the initial state and the surrounding configuration in the printer according to the first modification. FIG. 19 is a side view showing the solid lubricant 10Y in a state where it has been consumed until the end of its life in the printer according to the first modification and the surrounding configuration. In the printer according to the first modification, a distance sensor 156 is provided in place of the electrode for detecting a new article and the electrode for detecting the life. In addition, a test member 155 is fixed at a location facing the distance sensor 156 in the holding member 17Y. The distance sensor 156 detects the distance between itself and the test member 155 by reflection of ultrasonic waves, infrared rays, or the like. And based on the variation | change_quantity of the distance, the movement amount to the arrow B1 direction of the holding member 17Y is grasped | ascertained. Unlike the printer according to the embodiment that can detect only the movement amount corresponding to the new state to the life state, the fine movement of the holding member 17Y can be detected. For this reason, it is possible to have the user know how much time is left until the end of the service life and accurately grasp the timing of preparation for replacement of the solid lubricant 10Y.

[Second Modification]
FIG. 20 is an enlarged partial perspective view partially showing the inside of the lubricant application device for Y in the printer according to the second modification. In the printer according to the second modification, the relationship between the rail and the recess for guiding the oblique movement of the solid lubricant 10Y is opposite to that of the embodiment. Specifically, a guide groove GD is provided on the inner wall of the casing instead of the guide rail. The solid lubricant 10Y is provided with a guide rail-shaped convex portion 111Y instead of the inclined groove-shaped concave portion. The holding member 17Y and the solid lubricant 10Y are set so that the four protrusions 111Y provided on the solid lubricant 10Y are engaged with the four guide grooves GD provided on the inner wall of the casing. Thus, even if the relationship between the rail and the recess is opposite to that in the embodiment, the same effects as those in the embodiment can be obtained.

[Third Modification]
FIG. 21 is an enlarged partial perspective view partially showing the inside of the lubricant application device for Y in the printer according to the third modification. In the printer according to the third modification, instead of providing a recess in the solid lubricant 10Y as an inclined groove for engaging with the guide rail GL on the inner wall of the casing, a recess 18Y is provided in the metal holding member 17Y. .

  In the embodiment described above, the solid lubricant 10Y itself having excellent lubricity is provided with an inclined groove-like recess and is rubbed against the side surface of the guide rail GL so that the solid lubricant 10Y is moved along the guide rail GL. It can be moved smoothly. On the other hand, if the concave portion 11Y of the solid lubricant 10Y is strongly pressed against the guide rail GL, there is a demerit that the solid lubricant 10Y is liable to be cracked, cracked or chipped. Further, there is a demerit that the backlash of the solid lubricant 10Y is increased by expanding the width of the recess 11Y due to wear.

  On the other hand, in the printer according to the third modification, instead of the solid lubricant 10Y, the recess 18Y of the holding member 17Y made of a highly rigid metal is rubbed against the card rail GL so that the solid lubricant 10Y is guided to the guide rail. Generation | occurrence | production of the crack etc. of the solid lubricant 10Y by pressing strongly on GL can be avoided. Furthermore, since the metal recess 18Y is not consumed, the backlash of the solid lubricant 10Y due to the expansion of the width of the recess 18Y is not generated even when used for a long time. On the other hand, there is a demerit that the metal concave portion 10Y is easily hooked on the minute irregularities on the surface of the guide rail GL and the pressing failure of the solid lubricant 10Y is easily caused.

[Fourth Modification]
FIG. 22 is an enlarged partial perspective view partially showing the inside of the lubricant application device for Y in the printer according to the fourth modification. In the printer according to the fourth modification, instead of providing the solid lubricant 10Y with a convex portion as the engaging portion for engaging with the guide groove GD on the inner wall of the casing, the convex portion 119Y is provided on the metal holding member 17Y. This is different from the printer according to the second modification. It is possible to avoid the occurrence of cracking of the solid lubricant 10Y due to the solid lubricant 10Y being strongly pressed against the guide groove DG or the occurrence of rattling of the solid lubricant 10Y due to the widening of the recess. it can. On the other hand, there is a demerit that it is easy to cause the pressing failure of the solid lubricant 10Y by hooking the metal convex portion 119Y to the minute irregularities on the surface of the guide groove GD.

[Fifth Modification]
FIG. 23 is an enlarged partial perspective view partially showing the inside of the lubricant application device for Y in the printer according to the fifth modification. In the printer according to the fifth modification, in addition to the recess 11Y provided in the solid lubricant 10Y, the holding member 17Y is provided with a recess 18Y connected to the recess 11Y and having the same inclination as the recess 11Y. The point is different from the embodiment. The widths in the recesses are equal to each other. By pressing the recess 18Y of the holding member 17Y made of metal against the guide rail GL, the pressing force of the solid lubricant 10Y against the rail when some force is applied to the solid lubricant 10Y is reduced. Thereby, compared with the printer which concerns on embodiment, generation | occurrence | production of the crack etc. of the solid lubricant 10Y by pressing solid lubricant 10Y against the guide rail GL can be suppressed. Moreover, the breadth of the recessed part 11Y of solid lubricant 10Y can be suppressed, and the generation | occurrence | production of the shakiness of solid lubricant 10Y resulting from a breadth can also be suppressed. Moreover, the frictional force between the recess 18Y of the metal holding member 17Y and the guide rail GL is obtained by sliding the recess 11Y of the solid lubricant 10Y on the side of the guide rail GL and applying the lubricant powder to the side. Reduce. Accordingly, the holding member 17Y can be smoothly slid on the guide rail GL as compared with the printer according to the third modification. Further, since the holding member 17Y also has a recess 18Y that engages with the guide rail GL, even if the guide rail GL is made shorter, the solid lubricant 10Y on the holding member 17Y is brought to the contact position with the application brush roller 7Y. Can be moved.

[Sixth Modification]
FIG. 24 is an enlarged partial perspective view partially showing the inside of the lubricant application device for Y in the printer according to the sixth modification. In the printer according to the sixth modified example, in addition to providing the solid lubricant 10Y with the convex portion 111Y, the convex portion 119Y connected to the concave portion 111Y and having the same inclination as the convex portion 111Y is provided in the holding member 17Y. This is different from the printer according to the second modification. The widths of these convex portions are equal to each other.

  In the printer according to the second modification described above, the solid lubricant 10Y itself having excellent lubricity is provided with the inclined guide rail-shaped convex portion 111Y and is rubbed against the inner surface of the guide groove GD, thereby solid lubricant. 10Y can be smoothly moved along the guide groove GD. On the other hand, when the convex portion 111Y of the solid lubricant 10Y is strongly pressed against the guide groove GD, there is a demerit that the convex portion 111Y is likely to be cracked, cracked, chipped, or the like.

  On the other hand, in the printer according to the sixth modification, the pressing force of the solid lubricant 10Y against the guide groove GD of the convex portion 119Y of the solid lubricant 10Y is obtained by bringing the convex portion 111Y of the holding member 17Y made of metal into contact with the guide groove GD. To reduce. Thereby, compared with the printer according to the second modification, it is possible to suppress the occurrence of cracks and the like of the convex portion 111Y caused by pressing the convex portion 111Y of the solid lubricant 10Y against the guide groove GD. In addition, it is possible to suppress the reduction in the width of the convex portion of the solid lubricant 10Y and to suppress the occurrence of backlash in the solid lubricant 10Y due to the reduction. Moreover, the convex portion 119Y of the metal holding member 17Y and the guide groove GD are formed by sliding the convex portion 111Y of the solid lubricant 10Y on the inner surface of the guide groove GD and applying the lubricant powder to the inner surface. Reduce friction. Thereby, the holding member 17Y can be smoothly slid in the guide groove GD as compared with the printer according to the fourth modification. Further, since the holding member 17Y also has a convex portion 119Y that engages with the guide groove GD, even if the guide groove GD is made shorter, the solid lubricant 10Y on the holding member 17Y is in contact with the application brush roller 7Y. Can be moved to.

[Seventh Modification]
FIG. 25 is an enlarged partial perspective view partially showing the inside of the lubricant application device for Y in the printer according to the seventh modification. In the printer according to the seventh modification, of the plurality of inner wall surfaces in the casing of the lubricant application device, two inner wall surfaces Sa1 and inner wall surfaces that face each other across the solid lubricant 10Y disposed in the casing. Two guide rails GL are provided for the inner wall surface Sa2 which is one side of Sa2. Further, in the inner wall surface Sa1, which is the other, guide grooves GD are respectively provided at positions facing the two guide rails GL of the inner wall surface Sa2.

  In the solid lubricant 10Y, two convex portions 111Y for individually engaging with the two guide grooves GD of the inner wall surface Sa1 of the casing are provided at both ends in the lubricant longitudinal direction. Further, two concave portions 11Y for individually engaging with the two guide rails GL of the inner wall surface Sa2 of the casing are provided at both ends in the lubricant longitudinal direction. In the longitudinal direction of the lubricant, the position of the convex portion 111Y provided on one side surface in the width direction and the position of the concave portion 11Y provided on the other side surface are the same, and the convex portion 111Y and the concave portion 11Y are the lubricant. It faces in the width direction via.

  In the holding member 17Y, a recess 18Y for engaging with the guide rail GL or for receiving the guide rail GL in a non-contact manner is provided at a position communicating with each of the two recesses 11Y of the solid lubricant 10Y. .

  As described above, in the printer according to the seventh modification, among the two side surfaces aligned in the width direction of the solid lubricant 10Y, the convex portion 111Y is provided on one side surface, and the concave portion 11Y is provided on the other side surface. And the convex part 111Y and the recessed part 11Y are provided in the position which can mutually oppose in the width direction. The reason for adopting such a configuration is as follows. That is, it is assumed that only the convex portion 111Y is provided among the convex portion 111Y and the concave portion 11Y. Then, the dimension in the width direction of the solid lubricant 10Y varies depending on the position in the longitudinal direction of the lubricant. Specifically, in the lubricant longitudinal direction, the basic width dimension of the solid lubricant 10Y becomes the dimension in the width direction as it is at a place where the convex portion 111Y is not provided. On the other hand, in the longitudinal direction of the lubricant, in the location where the convex portion 111Y is provided, the width direction dimension of the solid lubricant 10Y is the basic width dimension described above and the amount of protrusion from the lubricant side surface of the convex portion 111Y. The value obtained by adding. That is, the dimension in the width direction is larger at the location where the convex portion 111Y is provided than at the location where the convex portion 111Y is not provided. The difference in dimension is directly the difference in the amount of lubricant scraped, and as a result, the difference in the amount of lubricant applied. In the rotation axis direction of the application brush roller 7Y, the lubricant application amount at a location corresponding to the convex portion 111Y of the solid lubricant 10Y is larger than the lubricant application amount at a location not corresponding to the convex portion 111Y. is there. In this way, when the lubricant application amount is different, there is a possibility of causing unevenness in the image quality of the formed image.

  Further, it is assumed that only the concave portion 11Y is provided among the convex portion 111Y and the concave portion 11Y. Then, in the rotation axis direction of the application brush roller 7Y, the lubricant application amount at a location corresponding to the recess 11Y of the solid lubricant 10Y becomes smaller than the lubricant application amount at a location not corresponding to the recess 11Y. In this way, even when the lubricant application amount is different, there is a risk of causing unevenness in the image quality of the formed image.

  Therefore, the convex portion 111Y is provided on one of the two side surfaces in the width direction of the solid lubricant 10Y, and the other side is opposed to the convex portion 111Y via the solid lubricant 10Y. A recess 11Y is provided on the surface. In such a configuration, as compared with the case where only the convex portion 111Y or only the concave portion 11Y is provided, the variation in the lubricant width direction in the lubricant longitudinal direction can be reduced, and the above-described unevenness in image quality can be suppressed. In the printer according to the tenth modification, the protruding amount of the convex portion 111Y and the concave amount of the concave portion 11Y are the same, and therefore, in the lubricant longitudinal direction, the portion where the convex portion 111Y and the concave portion 11Y are provided. The width of the lubricant is the same in the places where it is not provided. Therefore, it is possible to avoid the occurrence of the above-described image quality unevenness.

[Eighth Modification]
FIG. 26 is an exploded perspective view showing the solid lubricant 10Y for Y and the holding member 17Y in the printer according to the eighth modification. In the printer according to the eighth modification, a guide bar GB is provided instead of the guide rail as a guide portion for guiding the movement of the solid lubricant 10Y. The guide rod GB is provided in a posture protruding in an oblique direction toward the solid lubricant on the bottom wall surface (Sb in FIG. 11) of the casing. In this example, the guide rod GB is integrally formed with the bottom wall of the casing, but may be formed separately. In this case, the guide rod GB can be made of a material (for example, metal) different from that of the casing.

  The solid lubricant 10Y is provided with two holes 113Y for receiving the guide rod GB provided on the bottom wall of the casing. These holes 112Y are provided so as to be individually located at both ends in the longitudinal direction of the solid lubricant 10Y. Two guide rods GB described above are provided on the bottom wall of the casing so as to be individually inserted into the two holes 112Y.

  The holding member 17Y is also provided with through-holes 120Y for receiving the two guide bars GB individually at both ends in the longitudinal direction.

  When assembling the lubricant application device, first, the solid lubricant 10Y is fixed to the holding member 17Y. At this time, the solid lubricant 10Y is fixed to the holding member 17Y in such a posture that the hole 113Y of the solid lubricant 10Y communicates with the through hole 120Y of the holding member 17Y. Next, the solid lubricant 10Y and the holding member 17Y are set in the casing while the guide rod GB is inserted into the through hole 1209Y of the holding member 17Y and the hole 113Y of the solid lubricant 10Y. Thereafter, a coating brush roller (not shown) is set.

  The hole 113Y provided at each end of the solid lubricant 10Y, the through-hole 120Y provided at each end of the holding member, and the two guide rods GB provided on the bottom wall of the casing are all not shown. It is located in the area | region between the one end and the other end of the rotation axis direction in the brush roller part of a roller.

  The hole 113Y of the solid lubricant 10Y is not a through-hole penetrating from the lower end to the upper end in the thickness direction, but is provided with a digging-type hole portion that is dug down to a predetermined depth from the bottom portion. May be. Even in such a configuration, the solid lubricant 10Y can be moved in the thickness direction and moved in the brush axis direction, similarly to the configuration in which guide rails and guide grooves are provided.

[Ninth Modification]
FIG. 27 is a partially enlarged perspective view showing one end portion of the Y application brush roller 7Y in the printer according to the ninth modification. In the printer according to the ninth modified example, as shown in the drawing, the application brush roller 7 is provided with a spiral hair fallen wrinkle. The application brush roller 7 has a rotational axial force as well as a rotational force on a rubbing surface against a solid lubricant (not shown) as it rotates, similar to a spirally wound flocked brush sheet. Can be granted.

[Tenth Modification]
FIG. 28 is a perspective view showing a flocked brush sheet 9cY used for a Y application brush roller in a printer according to a tenth modification. In the figure, the flocking brush sheet 9cY has a flocking density in the sheet longitudinal direction (arrow X direction) lower than the flocking density in the sheet short direction (arrow Y direction). Specifically, in the illustrated flocked brush sheet 9cY, a raised bundling bundle of a plurality of raised bristles 9aY is implanted without gaps in the sheet lateral direction. On the other hand, in the longitudinal direction of the sheet, the raised bundles are planted at a certain interval.

  Such a flocked brush sheet 9cY is spirally wound around the peripheral surface of a roller portion of an application brush roller (not shown). At this time, unlike the embodiment, no gap is provided between the spirally wound sheets. Even if no gap is provided, a force in the rotation direction of the brush can be applied to the solid lubricant on the rubbing surface and a force in the direction of the rotation axis can be applied due to the deviation of the flock density.

[Eleventh Modification]
FIG. 29 is a perspective view showing a flocked brush sheet 9cY used for a Y application brush roller in a printer according to an eleventh modification. In the same figure, in the sheet | seat longitudinal direction (arrow X direction), the flocked brush sheet | seat 9cY has alternately flocked the raised bundle | bundle which bundled comparatively long raising part 9aY, and the raising bundle | flux which bundled comparatively short raising part 9aY. .

  Such a flocked brush sheet 9cY is spirally wound around the peripheral surface of a roller portion of an application brush roller (not shown). At this time, unlike the embodiment, no gap is provided between the spirally wound sheets. Even if no gap is provided, a force in the direction of rotation of the brush can be applied to the solid lubricant on the rubbing surface and a force in the direction of the axis of rotation can be applied to the solid lubricant due to deviation in the length of the hair.

[Twelfth Modification]
FIG. 30 is a side view showing the Y application brush roller 7Y, the solid lubricant 10Y, and the holding member 17Y in the printer according to the twelfth modification. For a photosensitive member (not shown), it is necessary to apply a lubricant to at least an image forming effective region in the rotation axis direction. Therefore, for the application brush roller 7Y, the length of the brush roller portion 9Y in the rotation axis direction is set to be larger than the length of the image forming effective area in the rotation axis direction of the photosensitive member. And about the solid lubricant 10Y moved to a brush rotating shaft direction, the length of a brush rotating shaft direction is made larger than the length of the brush roller part 9Y.

  The difference in length between the solid lubricant 10Y and the brush roller portion 9Y is set to be equal to or greater than the amount of movement of the solid lubricant 10Y in the brush rotation axis direction during the period from the initial state to the end of the life. Thereby, the solid lubricant 10Y can be kept in contact with the entire region in the rotation axis direction of the brush roller portion 9Y until the solid lubricant 10Y reaches the end of its life from the initial state.

  In the figure, θ represents an inclination angle of a guide rail (not shown). Along this inclination, the solid lubricant 10Y is pressed against the application brush roller 7Y. In the initial state, as shown in the drawing, the solid lubricant 10Y is set in a state in which both ends of the brush roller portion 9Y are opposite to the moving direction of the solid lubricant 10Y so that the solid lubricant 10Y protrudes from the end. . Assuming that the initial thickness of the solid lubricant 10Y is T, the amount of protrusion (= difference from the brush roller portion) is preferably “T / tan θ” or more. This is for the reason described below. In other words, in the drawing, tan θ is represented by “T / L1”. For this reason, L1 is represented by “T / tan θ”. The value indicates the total amount of movement of the solid lubricant 10Y in the rotation axis direction when it is assumed that all of the solid lubricant 10Y has been consumed. As described above, the solid lubricant 10Y has a life before it is completely consumed. Therefore, by setting L1 to “T / tan θ” or more, the solid lubricant 10Y can be reliably reached from the initial state to the end of the life. The brush roller portion 9Y can be kept in contact with the entire region in the rotation axis direction.

  FIG. 31 is a side view showing the solid lubricant 10Y at the end of its life and the surrounding configuration. At the end of the service life, as shown in the drawing, the longitudinal tip of the solid lubricant 10Y protrudes outward by a distance L2 from the end of the brush roller portion 9Y. As shown in the figure, the protruding lubricant portion generates a “uncut portion” having a taper that decreases from the outside to the center. This “uncut portion” should not be brought into contact with the rotating shaft member 8Y of the application brush roller 7Y.

  Therefore, in the twelfth modification, the amount of decrease in thickness from the initial state of the solid lubricant 10Y specified based on the detection result by the distance sensor 156 is reduced from the outer peripheral surface of the rotating shaft member 8Y of the application brush roller 7Y to the brush. Prior to reaching the same value as the distance to the outer peripheral surface of the roller portion 9Y, the CPU serving as notification means is configured to notify the arrival of the life of the solid lubricant 10Y. As a result, it is possible to avoid a situation in which the “uncut portion” is abutted against the rotary shaft member 8Y.

[Thirteenth Modification]
FIG. 32 is a side view showing the solid lubricant 10Y for Y in the printer according to the thirteenth modification, together with the surrounding configuration. In the drawing, the length of the application brush roller 7Y in the rotation axis direction of the brush roller portion 9Y is larger than the length in the rotation axis direction of the photoconductor 3Y as the application object. As shown in the figure, the brush roller end in the direction of the arrow B1, which is the direction of movement of the solid lubricant 10Y along the brush rotation axis, is arranged to protrude from the end of the photoreceptor.

  The solid lubricant 10Y has a length in the brush rotation axis direction that is greater than the length in the rotation axis direction of the photoreceptor 3Y. As in the case of the printer according to the twelfth modification, in the initial state, as shown in the figure, the end opposite to the arrow B1 direction as the moving direction is opposite to the arrow B1 direction of the brush roller portion 9Y. It is set in a state of projecting backward from the end on the side. The end protruding in this way is provided with a taper that approaches the coating brush roller 7Y from the end side (rear side) toward the center side. The tapered slope is provided along the extending direction of a guide rail (not shown), and the slope of the slope is the same as the slope of the guide rail.

  In FIG. 32, A1 indicates an image formation effective area in the rotation axis direction of the photoreceptor 3Y. As illustrated, both the brush roller portion 9Y of the application brush roller 7Y and the solid lubricant 10Y are located in the image forming effective area A1 of the photoreceptor 3Y. Further, in the initial state, the solid lubricant 10Y is set in a state where the front end in the direction of movement (the direction of the arrow B1) is positioned behind the front end of the brush roller portion 9Y as illustrated.

  FIG. 33 is a side view showing the solid lubricant 10Y together with the surrounding configuration at the time when the life has been reached. When the solid lubricant 10Y reaches the end of its life, as shown in the drawing, the rear end portion of the solid lubricant 10Y that protrudes rearward from the rear end of the brush roller portion 9Y in the initial state is in contact with the brush roller portion 9Y. It has moved forward to the position to make it. A taper is provided at the rear end portion as shown in FIG. 32, but when entering the contact position with the brush roller portion 9Y, the taper disappears as shown in FIG. This is because by making the taper the same inclination angle as the guide rail, the thickness of the taper portion entering the brush roller portion 9Y becomes the same as the thickness of the lubricant portion already rubbing against the brush roller portion 9Y. Accordingly, the solid lubricant 10Y is pressed against the brush by causing a lubricant portion having a thickness larger than that of the lubricant portion already rubbing against the brush roller portion 9Y to enter the rubbing surface of the brush roller portion 9Y. Generation of unevenness can be avoided.

  As shown in the drawing, the solid lubricant 10Y at the end of its life has moved to the point where the tip in the moving direction reaches the tip position of the brush roller portion 9Y. Unlike the twelfth modification, the tip of the solid lubricant 10Y is scraped by the brush roller 9Y until the end of its life, because the solid lubricant 10Y has a function of scraping at the tip of the brush roller 9Y. Taken. Therefore, it is possible to avoid the occurrence of “uncut portion” as in the twelfth modification.

[14th modification]
FIG. 34 is a side view showing the solid lubricant 10Y for Y in the printer according to the fourteenth modified example together with the surrounding configuration. In the drawing, the length of the application brush roller 7Y in the rotation axis direction of the brush roller portion 9Y is substantially the same as the length of the photoconductor 3Y in the rotation axis direction.

  The solid lubricant 10Y has a length in the brush rotation axis direction larger than the length of the brush roller portion 9Y of the application brush roller 7Y. As in the case of the printer according to the thirteenth modification, in the initial state, as shown in the figure, the end opposite to the arrow B1 direction as the moving direction is opposite to the arrow B1 direction of the brush roller portion 9Y. It is set in a state of projecting backward from the end on the side. The protruding end is provided with a taper similar to that of the thirteenth modification. The leading end of the solid lubricant 10Y in the moving direction is positioned substantially at the same position as the end of the image formation effective area of the photoreceptor 3Y in the initial state as shown in the figure. And the front-end | tip part is provided with the taper of the same direction and the same inclination angle as a rear-end part.

  FIG. 35 is a side view showing the solid lubricant 10Y together with the surrounding configuration at the time point when the life is reached. As shown in FIG. 34, the movement in the direction of the arrow B1 is started in a state where the tip of the solid lubricant 10Y is positioned substantially at the same position as the tip of the brush roller portion 9Y. As shown in the figure, the end of the service life is reached without generating the “uncut portion” as in the twelfth modification. This is because, as shown in FIG. 34, the same taper as the rear end portion is provided at the front end portion of the solid lubricant 10Y in the initial state.

[15th modification]
When the solid lubricant 10Y and the holding member 17Y are moved along the brush rotation axis direction, the coil spring 19Y that urges the holding member 17Y from the back side toward the application brush roller 7Y is largely curved as shown in FIG. This may make it difficult to achieve good urging. Therefore, in the printer according to the fifteenth modification, the coil spring 19Y is moved in the arrow B1 direction along the brush rotation axis along with the holding member 17Y.

  FIG. 37 is a partially enlarged perspective view showing the holding member 17Y of the printer according to the fifteenth modification together with the surrounding configuration. In the drawing, the holding member 17Y is fixed to the upper surface of a slide plate 130Y that is slidable in the direction of arrow B1 in the drawing. A coil spring (not shown) exists between the back surface of the holding member 17Y and the slide plate 130Y, and biases the holding member 17Y upward in the drawing.

A pin 17aY protrudes from the side surface of the holding member 17Y, and this pin 17aY is engaged with an elongated hole of an engaging portion provided in the slide plate 130Y. The engagement, in conjunction holding member 17Y is to move in the arrow B1 direction, also moves in the arrow B1 direction slide plate 1 30 Y as a supporting member. Then, a coil spring (not shown) fixed on the slide plate 1 30 Y also moves in the arrow B1 direction. In such a configuration, even if the holding member 17Y and the solid lubricant 10Y move in the direction of the arrow B1, the coil spring is also moved in the direction of the arrow B1 with the same movement amount, so the relative position between the coil spring and the holding member 17Y changes. I will not let you. Therefore, it is possible to avoid the occurrence of bending of the coil spring caused by changing the relative position between the holding member 17Y and the coil spring as the holding member 17Y is moved in the arrow B1 direction.

[Sixteenth Modification]
FIG. 38 is an enlarged configuration diagram illustrating a biasing mechanism for Y in the printer according to the sixteenth modification. In the printer according to the sixteenth modification, an urging mechanism shown in the figure is used instead of a coil spring as urging means for urging a holding member and a solid lubricant (not shown) toward the application brush roller. The urging mechanism has a cam member 131Y configured to be rotatable about a rotation shaft 132Y, and the cam member 131Y is pulled by a cam coil spring 133Y. As a result, a force for rotating the cam member 131Y in the clockwise direction in the drawing around the rotation shaft 132Y is applied.

  The tip of the cam member 131Y is in contact with the back surface of a holding member (not shown). In the drawing, the tip of the cam member 133Y that is about to rotate in the clockwise direction abuts against the holding member, thereby biasing the holding member toward a coating brush roller (not shown). In such a configuration, even if the holding member is moved along the brush axis direction, the urging direction of the cam member 133Y against the holding member is not changed. Therefore, unlike the case of biasing by the coil spring fixed to the main body, the holding member can be stably biased toward the application brush roller regardless of the position of the holding member in the brush rotation axis direction.

[17th modification]
FIG. 39 is a side view and a front view showing the Y application brush roller 7Y of the printer according to the seventeenth modified example together with its peripheral configuration. In the drawing, the holding member 17Y is supported so as to be slidable in the brush rotation axis direction on a rail (not shown) extending in the brush rotation axis direction. Further, the two coil springs 17Y that urge the holding member 17Y toward the application brush roller 17Y are both fixed on the slide plate 130Y described in the fifteenth modification, and an arrow is linked to the holding member 17Y. Move in the B1 direction.

  An axial coil spring 136 is in contact with the rear end of the holding member 17Y in the moving direction, and thereby a force in the direction of the arrow B1 is applied to the holding member 17Y. That is, in the seventeenth modification, the axial coil spring 136 functions as a moving force applying unit that applies a moving force in the brush rotation axis direction to the solid lubricant 10Y. Instead of or in addition to the axial coil spring 136, a force in the direction of the arrow B1 may be applied to the holding member 17Y by the application brush roller 7Y. The same applies to each modification described below.

  A tapered inclined surface Sa3 provided in the casing is in contact with the front end of the holding member 17Y in the moving direction. The inclined surface Sa functions as a part of the lubricant moving means, and is inclined with respect to the brush rotation axis direction (arrow B1 direction) and the thickness direction (arrow A direction) of the solid lubricant 10Y. When the thickness of the solid lubricant 10Y decreases from the state shown in the drawing and the solid lubricant 10Y moves toward the application brush roller 7Y, the tip of the holding member 17Y accordingly moves along the inclination on the inclined surface Sa. The holding member 17Y moves along the inclined surface Sa so as to rise. That is, in the printer according to the seventeenth modification, the holding member 17Y and the solid lubricant 10Y are moved in the thickness direction (arrow A direction) and the rotation axis direction (arrow B1 direction) as the thickness of the solid lubricant 10Y decreases. It is moved in a direction along the inclined surface Sa3 including both components. Thereby, solid lubricant 10Y can be moved in the direction of arrow B1 with a decrease in the thickness thereof.

  FIG. 40 is a side view and a front view showing the solid lubricant 10Y at the time of reaching the end of life together with the surrounding configuration. The tip of the holding member 17Y in the arrow B1 direction moves along the inclined surface Sa3 so as to ascend the inclined surface. Near the upper end of the inclined surface Sa, an electrode 137Y for life detection is fixed. When the thickness of the solid lubricant 10Y is reduced to the lifetime, the tip of the holding member 17Y reaches the position of the electrode 137. Then, the electrode 137 and the metal coil spring 19Y are electrically connected via the metal holding member 17Y. When CPU 135 detects the continuity, CPU 135 causes the display to display a message for informing the end of the life of solid lubricant 10Y.

  In such a configuration, the inclined surface Sa3 can be used as a fixing member for fixing the electrode 137 for life detection.

[18th modification]
The printer according to the eighteenth modification differs from the seventeenth modification only in the points described below. That is, FIG. 41 is an enlarged configuration diagram showing a taper provided inside the casing in the Y lubricant application device of the printer according to the eighteenth modified example together with the end of the solid lubricant 10Y. In the figure, the tapered inclined surface Sa3 is provided so as to change the inclination angle in two stages of a first inclination angle θ1 and a second inclination angle θ2. The second inclination angle θ2 is an inclination angle located on the upper side of the slope than the first inclination angle θ1, and is gentler than the first inclination angle θ1. In the illustrated inclined surface Sa3, as the inclination angle θ becomes gentle, the amount of movement of the solid lubricant in the arrow B1 direction increases as the thickness of the solid lubricant decreases by 1 [mm]. For a while for the first time after the solid lubricant 10Y is used in the initial state, the tip of the holding member 17Y moves along the slope portion having the slope angle θ1. After that, when the thickness of the solid lubricant 10Y is consumed to near the end of its life, the tip of the holding member 17Y moves along the slope portion having the slope angle θ2. Therefore, the amount of movement in the direction of the arrow B1 with respect to the decrease in thickness is greater when the thickness of the solid lubricant 10Y is consumed near the end of its life than in the initial state. That is, near the life, a decrease in the thickness of the solid lubricant is detected with higher sensitivity than in the initial state.

  In the printer according to the eighteenth modification, the second inclination angle θ2 is set to a value that can satisfy the condition “tan θ2 <1”. By setting in this way, the amount of movement of the solid lubricant 10Y in the direction of the arrow B1 when the thickness of the solid lubricant 10Y decreases by, for example, 1 [mm] is made larger than the amount of movement in the direction of the arrow A. . In such a configuration, the amount of movement of the solid lubricant in the arrow B1 direction is greater than the amount of decrease in the thickness of the solid lubricant. By detecting the amount of movement of the latter, it is possible to amplify and detect the decrease in thickness, so that the decrease in thickness can be detected with high sensitivity.

  The solid lubricant 10Y moves in the direction of the arrow B1 as it is consumed. However, the larger the total amount of movement in the direction of the arrow B1 until the solid lubricant in the initial state is consumed, the larger the amount of movement of the solid lubricant 10Y. Will increase in the direction. For this reason, it is necessary to keep the movement total amount to some extent. On the other hand, in order to detect the decrease in the thickness of the solid lubricant 10Y with high sensitivity, it is desirable to increase the amount of movement in the arrow B1 direction with respect to the amount of decrease in thickness as much as possible. May not fit.

  Therefore, in the printer according to the eighteenth modification, for the first time after using the solid lubricant 10Y in the initial state, the tip of the holding member 17Y is moved along the inclined surface portion having a relatively large inclination angle θ1, and the solid lubricant 10Y is moved. The amount of movement in the arrow B1 direction relative to the amount of decrease in the thickness of the lubricant 10Y is relatively small. Suppressing the enlargement of the apparatus by setting the direction of the arrow B1 per unit decrease in thickness relatively large rather than detecting the decrease in the thickness of the solid lubricant 10Y with high sensitivity when it is still far from the life Is prioritized. On the other hand, when the solid lubricant 10Y enters a period near the end of its life, the tip of the holding member 17Y is moved along the slope portion having a relatively small inclination angle θ2, thereby reducing the thickness of the solid lubricant 10Y. The amount of movement in the direction of the arrow B1 with respect to the amount is relatively large. Near the life, the decrease in the thickness of the solid lubricant 10Y is detected with high sensitivity, and the life arrival timing is detected with high accuracy. Therefore, in this printer, it is possible to suppress an increase in the size of the lubricant application device while accurately detecting the end of life.

[19th modification]
The printer according to the nineteenth modification is different from the eighteenth modification only in the points described below. FIG. 42 is an enlarged configuration diagram showing the taper provided inside the casing in the lubricant application device for Y of the printer according to the nineteenth modification, together with the end portion of the solid lubricant 10Y. As shown in the drawing, in the printer according to the nineteenth modification, the inclination angle near the upper end of the inclined surface Sa3 is not gentler than that on the lower end side, but the inclination angle is zero, that is, there is no inclination. A surface extending in the direction of the arrow B1 continues to the upper end of the inclined surface Sa3. Thus, the life detection electrode 137Y is fixed to the surface extending in the arrow B1 direction.

  For the first time that the solid lubricant 10Y is used from the initial state, the tip of the holding member 17Y moves along the inclined surface Sa3 in the drawing. When the solid lubricant 10Y is consumed to the end of its life, the solid lubricant 10Y reaches the upper end of the inclined surface Sa3 as shown in FIG. Then, the holding member 17Y and the solid lubricant 10Y move greatly at a stretch to the casing end along the surface in the arrow B1 direction. The reason why such a large movement can be made at a stretch is as follows. That is, when the tip of the holding member 17Y moves along the inclined surface Sa3, the holding member 17Y moves in the arrow B1 direction and the lubricant thickness direction (arrow A direction). Since the application brush roller is present in the lubricant thickness direction, the solid lubricant 17Y hits the brush. And it can move to the thickness direction only for the thickness reduction. For this reason, it can move little by little in the direction of arrow B1 by the amount corresponding to the thickness reduction. On the other hand, on the surface along the arrow B1 direction, the solid lubricant 10Y can be moved independently only in the direction of the arrow B1, without moving the solid lubricant 10Y in the arrow A direction. For this reason, the holding member 17Y moves at a stretch along the arrow B1 direction to the casing end by the biasing force of the axial coil spring. In this way, the arrival of the life can be detected with very high sensitivity by largely moving the holding member 17Y when the life is reached.

[20th modification]
The printer according to the twentieth modification differs from the seventeenth modification only in the points described below. That is, FIG. 44 is an enlarged configuration diagram showing the bending member provided inside the casing in the Y lubricant application device of the printer according to the twentieth modification together with the end of the solid lubricant 10Y. As shown in the figure, a curved surface Sa4 made of a curved member is provided in the casing instead of the inclined surface. The curved surface Sa4 moves the holding member 17Y that is in contact with the tip in a direction that includes both components of the lubricant thickness direction and the rotational axis direction (arrow B1 direction) as the thickness of the solid lubricant 10Y decreases. Let Thereby, similarly to the seventeenth modification, the solid lubricant 10Y is moved in the arrow B1 direction as the thickness decreases. The curved surface Sa4 functions as a part of the lubricant moving means.

[21st modification]
The printer according to the twenty-first modification differs from the twentieth modification only in the points described below. That is, as shown in FIG. 45, the following curvature change is given to the curved surface Sa4. The solid lubricant 10Y in a state where it has been consumed until the end of its life is more than the amount of movement in the direction of the arrow B1 as the solid lubricant 10Y in the initial state that has not been consumed is consumed by a predetermined thickness. This is a change in curvature that increases the amount of movement in the direction of the arrow B1 as the thickness is consumed. Thereby, similarly to the printer according to the eighteenth modification, it is possible to suppress the increase in the size of the lubricant application device while accurately detecting the life arrival timing.

[22nd modification]
FIGS. 46A and 46B are a side view and a front view showing the solid lubricant 10Y in the initial state in the printer according to the twenty-second modified example together with the surrounding configuration. FIG. 47 is a side view and a front view showing the solid lubricant 10Y at the time when the end of the life of the printer according to the twenty-second modified example is reached together with the surrounding configuration. As shown in these drawings, swingable arms 141Y are respectively connected to both ends of the holding member 17Y in the brush rotation axis direction. The holding member 17Y and the solid lubricant 10Y are supported in the casing by the two swinging arms 141Y constituting part of the lubricant moving means and the moving force applying means. The swinging arm 141Y is a tension coil spring. By 140Y, it is urged | biased toward the other end side from the one end side in a rocking | fluctuation track | orbit. As a result, the holding member 17Y and the solid lubricant 10Y move in a direction including both components in the lubricant thickness direction and the brush rotation axis direction.

  In such a configuration, the lubricant moving means for moving the solid lubricant 10Y in the brush rotation axis direction can also be used as the urging means for urging the solid lubricant 10Y toward the application brush roller.

[23rd modification]
The printer according to the twenty-third modification differs from the printer according to the seventeenth modification only in the points described below. That is, FIG. 48 is a side view showing the solid lubricant 10Y in the initial state together with the surrounding configuration. The solid lubricant 10Y in the initial state is provided with a step at the distal end in the moving direction so that the center side is thicker than the distal end side. And this front-end | tip part protrudes ahead rather than the front-end | tip of the holding member 17Y, and since the holding member 17Y is urged | biased by the axial direction coil spring 136Y, the front-end | tip of solid lubricant 10Y is a casing as an abutting member. It hits the inner wall. Thereby, the movement of the solid lubricant 10Y in the arrow B1 direction is prevented.

  When the thickness of the solid lubricant 10Y decreases to the end of its life, the thickness scraping amount from the initial state of the solid lubricant 10Y reaches the thickness of the tip of the solid lubricant 10Y. As a result, the thin end portion of the solid lubricant 10Y disappears. Then, the movement of the solid lubricant 10Y in the direction of the arrow B1 that has been blocked until the tip of the solid lubricant 10Y hits the casing is allowed. As shown in FIG. 49, the holding member 17Y and the solid lubricant 10Y are moved greatly in the direction of the arrow B1, and the tip of the holding member 17Y hits the inner wall of the casing. Then, the electrode 137 contacts the holding member 17Y, and the arrival of the life is detected by the CPU.

  In such a configuration, until the life of the solid lubricant 10Y comes to an end, the solid lubricant 10Y has a simple configuration in which the thin tip of the solid lubricant 10Y is abutted against the inner wall of the casing to prevent movement in the arrow B1 direction. The arrival of 10Y life can be detected.

  So far, a printer that forms a color image by a so-called tandem method has been described. However, the present invention can also be applied to a printer that forms only a monochrome image.

  As described above, in the printer according to the embodiment and each modified example, the movement amount detection unit including the electrode and the distance sensor that detects the movement amount of the holding member 17Y in the brush rotation axis direction, and the solid detection result based on the detection result. Since a CPU as a consumption amount grasping means for grasping the consumption amount of the lubricant 10Y is provided, the consumption amount in the thickness direction of the solid lubricant 10Y is grasped based on the movement amount of the holding member 17Y in the brush rotation axis direction. Can do.

  Further, in the printer according to the embodiment and each modified example, the lubricant moving unit is configured to move the solid lubricant 10Y in the brush axis direction by a moving amount larger than the thickness reduction amount. In such a configuration, as described above, the thickness reduction can be detected with high sensitivity by amplifying and detecting the thickness reduction amount of the solid lubricant 10Y.

  Further, in the printer according to the embodiment and each modified example, the rotating shaft member 8Y that is rotatably supported as the application member, and the brush roller portion 9Y that includes a plurality of raised brushes erected on the peripheral surface thereof are provided. The coating brush roller 7Y provided is used. The solid lubricant 10Y is moved along the brush rotation axis direction as the thickness decreases. In such a configuration, the amount of decrease in the thickness of the solid lubricant 10Y can be grasped based on the amount of movement of the holding member 17Y along the brush rotation axis direction.

  In the printers according to the embodiments, the first to seventh, and the ninth to sixteenth modified examples, the guide rail GL or the guide groove GD each having an inclination inclined with respect to the brush rotation axis direction and the lubricant thickness direction is provided. The solid lubricant 10Y or the holding member 17Y that is provided and engages with the guide rail GL or the guide groove GD includes the components in both the lubricant thickness direction and the brush rotation axis direction as the thickness of the solid lubricant 10Y decreases. It is made to move in the direction along the rail GL or the guide groove GD. In such a configuration, the solid lubricant 10Y can be moved in the brush axis direction as the thickness thereof decreases while the movement of the solid lubricant 10Y or the holding member 17Y is guided by the guide rail GL or the guide groove GD.

  Further, in the printers according to the first to seventh modified examples and the ninth to sixteenth modified examples, the solid lubricant 10Y or holding the concave portion that engages with the guide rail GL or the convex portion that engages with the guide groove GD. Since the member 17Y is provided, the solid lubricant 10Y and the holding member 17Y can be moved along the guide rail GL and the guide groove GD by the engagement.

  In the printer according to the eighth modification, a solid bar that is provided on the bottom surface of the casing and has a guide bar GB that is inclined with respect to the brush rotation axis direction and the lubricant thickness direction and is engaged with the guide bar GB. The lubricant 10Y and the holding member 17Y are moved in a direction along the guide rod GB including components in both the lubricant thickness direction and the brush rotation axis direction as the thickness of the solid lubricant 10Y decreases. In such a configuration, the solid lubricant 10Y can be moved in the brush axis direction as the thickness thereof decreases while guiding the movement of the solid lubricant 10Y or the holding member 17Y by the guide rod GB.

  In the printer according to the eighth modification, since the hole for receiving the guide rod GB is provided in the solid lubricant 10Y and the holding member 17Y, the solid lubricant 10Y and the holding member 17Y are arranged along the guide rod GB. Can be moved.

  In the printers according to the seventeenth to nineteenth modified examples, the inclined surface Sa3 that is inclined with respect to the brush rotation axis direction and the lubricant thickness direction is provided, and the holding member 17Y is held while being abutted against the inclined surface Sa3. The member 17Y and the solid lubricant 10Y are moved in a direction along the inclined surface Sa3 including components in both the lubricant thickness direction and the brush rotation axis direction as the thickness of the solid lubricant 10Y decreases. In this configuration, as already described, the solid lubricant 10Y can be moved in the brush axis direction as the thickness thereof decreases while the movement of the holding member 17Y is guided by the inclined surface Sa3. Furthermore, the inclined surface Sa3 can be used as a fixing means for fixing the life detection electrode 137Y.

  Further, in the printer according to the eighteenth modification, the solid lubricant 10Y in the initial state that has not been consumed is closer to the end of its service life than the amount that the solid lubricant 10Y is moved in the brush rotation axis direction as it is consumed by a predetermined thickness. As the solid lubricant 10Y in the consumed state is consumed by a predetermined thickness, the brush rotation is changed in at least two stages. In such a configuration, as already described, it is possible to suppress the increase in size of the lubricant application device while accurately detecting the life arrival timing. In the printers according to the first to seventh modification examples and the ninth to sixteenth modification examples, the inclination angle of the guide rail Gl or the guide groove GC may be similarly changed in at least two stages.

  In the printers according to the twentieth to twenty-first modifications, the holding member 17Y and the solid lubricant 10Y are placed on the solid lubricant 10Y while providing the curved surface Sa4 and abutting the tip of the holding member 17Y on the curved surface Sa4. As the thickness is decreased, the lubricant is moved in a direction along the curved surface Sa3 including components in both the lubricant thickness direction and the brush rotation axis direction. In such a configuration, the solid lubricant 10Y can be moved in the brush axial direction as the thickness thereof decreases while guiding the movement of the holding member 17Y by the curved surface Sa4. Furthermore, the curved surface Sa4 can be used as a fixing means for fixing the life detection electrode 137Y.

  Further, in the printer according to the twenty-first modified example, the lifetime of the solid lubricant 10Y in the initial state that has not been consumed is closer to the life than the amount that the solid lubricant 10Y is moved in the brush rotation axis direction as it is consumed by a predetermined thickness. The curvature of the curved surface Sa4 is changed in at least two stages so as to increase the amount of the solid lubricant 10Y in the consumed state to be moved in the brush rotation axis direction as it is consumed by a predetermined thickness. Yes. In such a configuration, as already described, it is possible to suppress the increase in size of the lubricant application device while accurately detecting the life arrival timing.

  In the twenty-third modification, a thickness deviation that increases from the tip side toward the center side is provided at the tip of the solid lubricant 10Y in the brush rotation axis direction. And the solid lubricant 10Y is urged | biased toward the casing inner wall in the state which butted the front-end | tip part of solid lubricant 10Y to the casing inner wall which is a butting member. In this configuration, as already described, until the lifetime of the solid lubricant 10Y comes to an end, the thin tip of the solid lubricant 10Y abuts against the inner wall of the casing to prevent the movement in the arrow B1 direction. Thus, the end of the life of the solid lubricant 10Y can be detected.

  Further, in the printer according to the embodiment and each modification, since the moving force applying means for applying the moving force in the brush rotation axis direction is provided to the solid lubricant 10Y, the solid lubricant 10Y is used as the brush rotation axis. It can be possible to move in the direction.

  In the printer according to the embodiment and the first to sixteenth modifications, the solid lubricant on the rubbing surface with the solid lubricant 10Y due to the arrangement deviation, the rigidity deviation, the flocking density deviation, or the hair falling wrinkles of the raised 9aY. The application brush roller 7Y is configured to function as a moving force applying means by applying a force in the brush rotation axis direction in addition to a force in the brush rotation direction to 10Y. In such a configuration, it is possible to apply a moving force in the brush rotation axis direction to the solid lubricant 10Y using the rotational force of the application brush roller 7Y.

  In the printer according to the twelfth modification, the solid lubricant 10Y has a length in the brush rotation axis direction larger than the length of the brush roller portion 9Y of the application brush roller 7Y, and the difference in length is in the initial state. The amount of solid lubricant 10Y that is equal to or greater than the amount of movement of the solid lubricant 10Y in the brush rotation axis direction is used. In this configuration, as already described, the solid lubricant 10Y can be kept in contact with the entire region in the rotation axis direction of the brush roller portion 9Y until the solid lubricant 10Y reaches the end of its life from the initial state. .

  In the printer according to the twelfth modified example, the amount of decrease in thickness from the initial state of the solid lubricant 10Y grasped by the CPU as the consumption grasping means is from the outer peripheral surface of the rotating shaft member 8Y of the application brush roller 7Y. Prior to reaching the same value as the distance to the outer peripheral surface of the brush roller portion 9Y, the CPU serving as notification means is configured to notify the end of the life of the solid lubricant 10Y. In this configuration, as described above, it is possible to avoid a situation in which the “uncut portion” of the solid lubricant 10Y hits the rotating shaft member 8Y.

  In the printer according to the thirteenth modification, the solid lubricant 10Y is applied to the end portion (rear end portion) opposite to the moving direction along the brush rotation axis direction from the end side toward the center side. A taper that approaches the brush roller 7Y is used. In such a configuration, as already described, a solid portion by causing a lubricant portion having a thickness greater than that of the lubricant portion already rubbing against the brush roller portion 9Y to enter the rubbing surface of the brush roller portion 9Y. Occurrence of uneven pressing on the brush of the lubricant 10Y can be avoided.

  Further, in the printer according to the fourteenth modification, the application brush roller 7Y uses a brush roller portion 9Y whose length in the rotation axis direction is larger than the length of the photoconductor 3Y in the brush rotation axis direction. A solid lubricant 10Y having a length in the brush rotation axis direction larger than the length of the photoreceptor 3Y is used. In such a configuration, as described above, the tip portion can be continuously cut until the end of its life without generating a “uncut portion” at the tip portion of the solid lubricant 10Y.

  In the printer according to the fifteenth modification, a slide plate 130Y is provided as a support member that supports the coil spring 19Y as an urging means so as to be movable along the brush rotation axis direction, and the solid lubricant 10Y and the brush of the holding member 17Y are provided. The slide plate 130Y is moved in the brush rotation axis direction in conjunction with the movement in the rotation axis direction. In this configuration, as described above, it is possible to avoid the occurrence of bending of the coil spring caused by changing the relative position between the holding member 17Y and the coil spring as the holding member 17Y is moved in the arrow B1 direction. it can.

  In the printer according to the sixteenth modification, as a biasing means, the rotatable cam member 131 is pressed against the holding member 17Y, and the holding member 17Y and the solid lubricant 10Y are biased toward the application brush roller 7Y. Use what you want. In this configuration, as already described, unlike the case where the coil spring fixed to the main body is used for urging, the holding member is stably directed toward the application brush roller regardless of the position of the holding member in the brush rotation axis direction. You can

  Further, in the printer according to the twenty-second modified example, the swing arm 141Y is supported from one end side of the swing track while the both ends of the holding member 17Y in the brush rotation axis direction are supported by swingable swing arms 141Y. The holding member 17Y and the solid lubricant 10Y are biased toward the other end side to move in a direction including both components in the lubricant thickness direction and the brush rotation axis direction. In this configuration, as already described, the lubricant moving means for moving the solid lubricant 10Y in the brush rotation axis direction can be used as the urging means for urging the solid lubricant 10Y toward the application brush roller. it can.

  Further, in the printer according to the embodiment and each modified example, the electrode or the distance sensor as the movement amount detecting means is disposed on the side of the solid lubricant 10Y or the holding member 17Y in the brush axis direction. Even when there is no space for arranging electrodes and distance sensors in the thickness direction of the agent 10Y, the movement of the solid lubricant 10Y in the brush axis direction can be detected.

3Y, M, C, K: photoconductor (coating body)
7Y: Application brush roller (application member)
8Y: Rotating shaft member 9Y: Brush roller portion 10Y: Solid lubricant 17Y: Holding member 19Y: Coil spring (biasing means)

JP 2008-541750 A

Claims (26)

Solid lubricant,
An application member for applying the lubricant powder scraped from the solid lubricant to an object to be applied;
A holding member for holding the solid lubricant;
A lubricant applying device comprising a biasing means to abut the solid lubricant on the holding member to the applying member to urge the holding member,
Lubricant moving means for moving the solid lubricant in a direction orthogonal to the application member surface movement direction on the rubbing surface between the solid lubricant and the application member ;
The coating member applies lubricant powder scraped from the solid lubricant to the coated body as the surface of the coating member moves endlessly in contact with the solid lubricant and the coated body. Yes,
In addition, the lubricant moving means moves in a direction orthogonal to the moving direction of the application member surface on the rubbing surface between the solid lubricant and the application member, with a movement amount corresponding to the reduction amount of the thickness of the solid lubricant. A lubricant application apparatus for moving a solid lubricant . The lubricant application device according to claim 1 , wherein
A lubricant application device comprising: a movement amount detection means for detecting a movement amount in the orthogonal direction; and a consumption amount grasping means for grasping a consumption amount of the solid lubricant based on a detection result thereby. . The lubricant application device according to claim 2 ,
The lubricant application device, wherein the lubricant moving means moves the solid lubricant in the orthogonal direction by a movement amount larger than a thickness reduction amount. The lubricant application device according to claim 2 or 3 ,
The coating member is a coating brush roller including a rotating shaft member that is rotatably supported, and a brush roller unit that includes a plurality of raised brushes erected on the peripheral surface thereof.
And the said orthogonal direction is a rotating shaft direction of the said application brush roller, The lubricant application device characterized by the above-mentioned. The lubricant application device according to claim 4 ,
The solid lubricant engaged with the guide rail or the guide groove, the lubricant moving means having a guide rail or a guide groove each having an inclination inclined with respect to the rotation axis direction and the thickness direction of the solid lubricant. The lubricant or the holding member is moved in a direction along the guide rail or the guide groove including the components in both the thickness direction and the rotation axis direction as the thickness of the solid lubricant decreases. A lubricant applicator characterized. The lubricant application device according to claim 5 ,
The lubricant application device, wherein the solid lubricant or the holding member has a concave portion that engages with the guide rail or a convex portion that engages with the guide groove. The lubricant application device according to claim 4 ,
The lubricant moving means has a guide bar having inclinations respectively inclined with respect to the rotation axis direction and the thickness direction of the solid lubricant, and the solid lubricant and the holding engaged with the guide bar Lubricant application characterized in that the member is moved in a direction along the guide bar including components in both the thickness direction and the rotational axis direction as the thickness of the solid lubricant decreases. apparatus. The lubricant application device according to claim 7 ,
The lubricant applying apparatus, wherein the solid lubricant and the holding member have a hole portion that engages with the guide rod. The lubricant application device according to claim 4 ,
The lubricant moving means has inclined surfaces that are inclined with respect to the rotation axis direction and the thickness direction of the solid lubricant, and abuts one end of the holding member in the rotation axis direction against the inclined surface, The holding member and the solid lubricant are moved in a direction along the inclined surface including components in both the thickness direction and the rotation axis direction as the thickness of the solid lubricant decreases. Lubricant application device. The lubricant application device according to claim 5, 6 or 9 ,
The solid lubricant in a state where it is consumed to near the end of its life, rather than the amount of the solid lubricant in the initial state that is not consumed is moved in the rotational axis direction as it is consumed by a predetermined thickness, The inclination angle of the guide rail, the guide groove or the inclined surface is changed in at least two stages so as to increase the amount of movement in the direction of the rotation axis as the predetermined thickness is consumed. Lubricant application device. The lubricant application device according to claim 4 ,
The lubricant moving means has a curved surface, and the holding member and the solid lubricant are reduced in thickness of the solid lubricant while abutting one end of the holding member in the rotational axis direction against the curved surface. Along with this, the lubricant application device is moved in a direction along the curved surface including both components in the thickness direction and the rotation axis direction. In the lubricant applying device of claim 1 1,
The solid lubricant in a state where it is consumed to near the end of its life, rather than the amount of the solid lubricant in the initial state that is not consumed is moved in the rotational axis direction as it is consumed by a predetermined thickness, The lubricant applying apparatus according to claim 1, wherein the curvature of the curved surface is changed in at least two stages so as to increase the amount of movement in the direction of the rotation axis as the predetermined thickness is consumed. The lubricant application device according to claim 4 ,
The solid lubricant is provided with a step at one end portion in the rotation axis direction that has a thicker central side than one end side in the rotation axis direction,
The lubricant moving means urges the solid lubricant toward the abutting member in a state where the one end of the solid lubricant is abutted against the abutting member. Lubricant application device. In any of the lubricant applying device according to claim 5 to 1 3,
A lubricant application device comprising a moving force applying means for applying a moving force in the direction of the rotation axis to the solid lubricant. In the lubricant applying device according to claim 1 4,
The application brush roller applies the force in the endless movement direction to the solid lubricant on the sliding surface with the solid lubricant due to the arrangement deviation, rigidity deviation, flocking density deviation, or hair fallen wrinkle of the raised brush. The lubricant applying device functions as the moving force applying means by applying a force in the direction of the rotation axis. In any of the lubricant applying device according to claim 5 to 1 5,
As the solid lubricant, the rotation axis direction length of the solid lubricant is larger than the length of the brush roller portion of the application brush roller, and the difference in length from the initial state to the end of the life of the solid lubricant. A lubricant application device using a device that is equal to or greater than the amount of movement in the direction. The lubricant application device according to claim 16 ,
The thickness reduction amount from the initial state of the solid lubricant specified based on the grasping result by the consumption grasping means is from the outer peripheral surface of the rotating shaft member of the application brush roller to the outer peripheral surface of the brush roller portion. Prior to reaching the same value as this distance, a lubricant application device is provided, which provides a notification means for notifying the end of the life of the solid lubricant. The lubricant application device according to claim 16 or 17 ,
As the solid lubricant, one having a taper that approaches the coating brush roller as it goes from the end side to the center side at the end opposite to the moving direction along the rotation axis direction was used. A lubricant applicator characterized. In any of the lubricant applying device according to claim 5 to 1 5,
As the application brush roller, a brush roller portion having a length in the rotation axis direction larger than the rotation axis direction length of the coated body is used,
A lubricant coating apparatus using the solid lubricant having a length in the rotation axis direction larger than a length in the rotation axis direction of the object to be coated. In the lubricant application device according to any one of claims 1 to 19 ,
A support member is provided for supporting the urging means so as to be movable along the rotation axis direction, and the support member is moved in the rotation axis direction in conjunction with the movement of the solid lubricant and the holding member in the rotation axis direction. A lubricant application device characterized in that the device is moved to. In the lubricant application device according to any one of claims 1 to 19 ,
Lubricant application apparatus using the urging means as a member that presses a rotatable cam member against the holding member and urges the holding member and the solid lubricant toward the application member. . The lubricant application device according to claim 4 ,
The lubricant moving means attaches the swinging arm from one end side to the other end side of the swinging track while supporting both ends of the holding member in the rotation axis direction by swingable swinging arms. The lubricant application device is characterized in that the holding member and the solid lubricant are moved in a direction including both components in the thickness direction and the rotation axis direction. In the lubricant application device according to any one of claims 2 to 19 or claims 22 to 23 ,
The lubricant application apparatus according to claim 1, wherein the movement amount detecting means is disposed on a side of the solid lubricant or the holding member in the orthogonal direction. An image forming apparatus comprising: an image carrier that carries a toner image; a toner image forming unit that forms a toner image on a surface of the image carrier; and a lubricant application unit that applies a lubricant to the surface of the image carrier.
As the lubricant application means, the image forming apparatus characterized by using either of the lubricant applying device according to claim 1 or 2 3. Used in an image forming apparatus comprising: an image carrier that carries a toner image; a lubricant application device that applies a lubricant to the surface of the image carrier; and a toner image forming unit that forms a toner image on the surface of the image carrier. ,
At least a process unit configured such that the image carrier and the lubricant application device are held by a common holder and can be integrally attached to and detached from the image forming apparatus main body as a unit.
Process units the lubricant coating device, characterized in that it is a one of a lubricant coating apparatus according to claim 1 or 2 3. An application member that applies the lubricant powder scraped from the solid lubricant to the object to be coated as it rotates while contacting the solid lubricant and the object to be coated, and a holder that holds the solid lubricant. A solid lubricant mounted on a lubricant application device comprising: a member; and an urging means for urging the holding member to bring the solid lubricant on the holding member into contact with the application member,
The recess corresponding to the guide rail in the lubricant applying device according to claim 6, or are provided with the convex portion, corresponding to the guide groove or the guide rods in the lubricant applying device according to claim 8 A solid lubricant comprising the hole corresponding to the above.

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