This application claims priority from Japanese Patent Application No. 2013-203247, filed on Sep. 30, 2013, the entire subject matter of which are incorporated herein by reference.
1. Field
Aspects of the present invention relate to an image forming apparatus in an electrophotographic method and to a fuser of the image forming apparatus, and more particularly to an image forming apparatus equipped with a fuser in a belt fixing method.
2. Description of the Related Art
In general, an image forming apparatus in an electrophotographic method includes an image supporting body structured so that a developing agent such as toner can be supported, a transfer member that transfers the developing agent supported on the image supporting body to a recording sheet, and a fuser that thermally fixes the developing agent transferred to the recording sheet. In a known method used by a fuser, an endless belt (fixing film) is held between a nip member placed so as to face the inner surface of the belt and a rotating body (pressurizing roller) placed so as to face the outer surface of the belt, after which the developing agent is heated to melt it and the melted developing agent is fixed on the recording sheet in a process in which the recording sheet on which the developing agent is supported is conveyed while being held between the belt and the rotating body.
As for a fuser based on this method, a structure is known in which fluid guide grooves are formed in a surface, of the nip member, that is in contact with the belt to evenly distribute a lubricant used to enhance slidability between the nip member and the belt.
Because of design considerations for a recording sheet conveying path in the image forming apparatus, the nip member and rotating body are placed so that the contact portion of the nip member faces downward as in Japanese Unexamined Patent Application Publication No. 2008-146964. In addition to this aspect, an aspect in which the contact portion of the nip member is oriented at an angle as indicated in FIG. 1 in U.S. patent publication no. 2009/0175645 has been practiced.
In the structure described in Japanese Unexamined Patent Application Publication No. 2008-146964, a lubricant can be evenly distributed on the contact portion of the nip member, but there is no consideration for the lubricant flowing outwardly from the contact portion. If the lubricant flows outwardly from the contact portion, the lubricant may proceed along the smooth surface of the nip member and may turn back and enter the back of the nip member. As a result, the lubricant may contaminate the interior of the apparatus. In addition, if the amount of lubricant is reduced due to its outward flow, the slidability of the belt may be reduced. Then, the driving torque of the belt may be increased and the belt becomes more likely to slip. Furthermore, the apparatus may be deteriorated earlier than expected.
Particularly in the structure described in U.S. patent application No. 2009/0175645, in which the contact portion of the nip member is oriented at an angle, if the lubricant overflows from the contact portion of the nip member and enters the interior of the fusing device from the downstream end of the nip member, the lubricant may contaminate a heating element, a reflecting plate, which reflects radiant heat from the heating element, and other components in the fuser. This may lower the performance of the fuser.
Noting the issue of suppressing a lubricant from flowing out from the upwardly oriented contact portions of the nip member and other members in a fuser, particularly from the downstream end of the contact portion in a direction in which a recording sheet is conveyed (belt sliding direction), the inventors of this application repeated diligent study and devised the present invention.
According to the aspects of the disclosure, an image forming apparatus may include a main body having a bottom surface, a photosensitive drum away from the bottom surface, and a fuser having at least a portion disposed further away from the bottom surface than the photosensitive drum. The fuser may include an endless belt, a rotatable body, and a nip plate. The nip plate may include a first surface with lubricant thereon that faces an inner surface of the endless belt, and the second surface that extends from an end of the first surface. The first surface and the rotatable body may be configured to nip the endless belt there between, and the endless belt and the rotatable body may be configured to form a nip therebetween. The second surface may include the furthest downstream portion of the nip plate along the conveying path and may be spaced away from the inner surface of the endless belt.
According to other aspects of the disclosure, an image forming apparatus may include a main body having a bottom surface, a photosensitive body away from the bottom surface, and a fuser disposed further away from the bottom surface than the photosensitive body. The fuser may include an endless belt, a rotatable body, and a nip plate. The nip plate may include a first surface with lubricant thereon that faces an inner surface of the endless belt, and the second surface that extends from an end of the first surface. The first surface and the rotatable body may be configured to nip the endless belt there between, and the endless belt and the rotatable body may be configured to form a nip therebetween. The endless belt may be configured to move in a moving direction at the nip. The second surface may include the furthest downstream portion of the nip plate in the moving direction and may be spaced away from the inner surface of the endless belt.
According to still other aspects of the disclosure, an image forming apparatus may include a main body having a bottom surface, a photosensitive body away from the bottom surface, and a fuser disposed further away from the bottom surface than the photosensitive body. The fuser may include an endless belt, a rotatable body, and a nip forming assembly. The nip forming assembly may include a first surface with lubricant thereon that faces an inner surface of the endless belt, and the second surface that extends from an end of the first surface. The first surface and the rotatable body may be configured to nip the endless belt therebetween, and the endless belt and the rotatable body may be configured to form a nip therebetween. The endless belt may be configured to move in a moving direction at the nip. The second surface may include a downstream end in the moving direction and may be spaced away from the inner surface of the endless belt.
An illustrative embodiment of the present invention will be described with reference to the drawings at appropriate points. In the descriptions below, directions are determined with respect to the user who uses the image forming apparatus. Specifically, the left side in
First, the entire structure of an image forming apparatus in an illustrative embodiment will be described.
As illustrated in
The case 2 is mainly structured with a main body 21, which supports the photosensitive drum 41 and the like, and a front cover 22. The main body 21 has a bottom B that has a bottom surface (BS). The main body 21 has a plurality of supports (SP), each of the plurality of supports (SP) protruding from the bottom surface (BS). Each of the plurality of supports (SP) is softer than the bottom and includes gum. An imaginary line is tangent to the a bottom surface of two of the plurality of supports (SP). In other words, the support (SP) is a foot. The main body 21 has an opening 21A in the front surface. A development cartridge 44 described later is attached and removed through the opening 21A.
The front cover 22, which covers the opening 21A on the front side as indicated by the dash-dot-dot lines, is supported so that the upper end of the front cover 22 can swing around its lower end with respect to the main body 21. While being open as indicated by the solid lines, the front cover 22 is part of a feed tray 31 described later. The case 2 has a second front cover 24, which is placed inside the front cover 22 in the closed state indicated by the dash-dot-dot lines. The second front cover 24 opens and closes the opening 21A by swinging around its lower end. Thus, even while the front cover 22 is open and is being used as part of the feed tray 31, the second front cover 24 can suppress dust from entering the interior of the case 2.
The sheet feeding unit 3, which is structured so as to supply the sheet S to the image forming unit 4, mainly includes the feed tray 31 and a sheet feeding mechanism 33. The feed tray 31 is a tray on which sheets S to be fed to the image forming unit 4 are stacked.
The feed tray 31 is formed with a pressing plate 31A disposed at the bottom in the case 2 and a base used together with the front cover 22 in the open state to allow sheets S to be stacked. The pressing plate 31A is supported so that its rear end can vertically swing around its front end with respect to the main body 21. The rear end is lifted by a lifting member 31B.
The sheet feeding mechanism 33 includes a pickup roller 33A, a separating roller 33B, a separating pad 33C, and the like. The sheet feeding mechanism 33 is placed near the back at the bottom in the case 2. In the sheet feeding mechanism 33, the pickup roller 33A feeds sheets S stacked on the feed tray 31, and the sheets S are separated between the separating roller 33B and the separating pad 33C and are fed to the image forming unit 4 one sheet S at a time.
The image forming unit 4 is structured so as to form an image on a fed sheet S. It mainly includes the photosensitive drum 41, which is an example of an image supporting body, a charging unit 42, an exposing unit 43, a development cartridge 44, a transfer roller 45, which is an example of a transfer member, and a fuser 100.
The photosensitive drum 41 is formed by forming a photosensitive layer on the outer circumferential surface of a cylindrical conductive drum body. The photosensitive drum 41 is placed near the back in the case 2 in the vicinity of the vertical center so as to be rotatable in the direction indicated by the arrow in
The charging unit 42, which includes corona wires and grid electrodes, is placed so as to face the top of the photosensitive drum 41. The charging unit 42 evenly charges the surface of the photosensitive drum 41 by applying a charging bias to the surface.
The exposing unit 43 includes a plurality of turned-on and turned-off parts (not illustrated), which are light emitting diodes, arrayed in the right and left direction, in which the axis of the photosensitive drum 41 rotates. The exposing unit 43 is placed so as to face a forward and upper portion of the photosensitive drum 41. The exposing unit 43 enables the charged surface of the photosensitive drum 41 to be exposed to light by turning on and off the turned-on and turned-off parts according to image data.
The development cartridge 44 includes a developing roller 44A, a supply roller 44B, a layer thickness restricting blade 44C, a toner storage 44D in which toner is stored, and the like. The development cartridge 44 is placed so as to face a forward and lower portion of the photosensitive drum 41. The development cartridge 44 supplies toner to the electrostatic latent image formed on the photosensitive drum 41 by an exposure so that a toner image is formed on the photosensitive drum 41. With the front cover 22 and second front cover 24 in the open state, the development cartridge 44 can be attached to and removed from the case 2 through the opening 21A, enabling the development cartridge 44 to be replaced.
The transfer roller 45 includes a metal axis, an elastic roller body formed around the axis, and the like. The transfer roller 45 is placed so as to face the back of the photosensitive drum 41. The transfer roller 45 applies a transfer bias to draw toner and transfer a toner image to a sheet S passing between the transfer roller 45 and the photosensitive drum 41.
The fuser 100 includes a heating member 101, a pressurizing roller 150, and the like. The fuser 100 is placed above the photosensitive drum 41 in the case 2. The fuser 100 thermally fixes the toner image transferred to the sheet S passing between the heating member 101 and the pressurizing roller 150. The structure of the fuser 100 will be described later in detail.
The discharge unit 5 mainly includes a discharge roller 51 and a discharge tray 52 to discharge the sheet S on which an image has been formed. Specifically, the discharge roller 51 discharges, to the outside of the case 2, the sheet S on which an image has been formed and conveyed from the fuser 100. The discharge roller 51 is placed at an upper portion in the interior of the case 2. The discharge tray 52 accepts the sheet S discharged to the outside of the case 2. The discharge tray 52 is placed on the upper surface of the main body 21.
When receiving a command, including image data, to form an image, the laser printer 1 structured as described above executes an image forming operation. Specifically, in the image forming unit 4, the charging unit 42 charges the surface of the photosensitive drum 41, which is rotationally driven, after which the exposing unit 43 exposes the charged surface of the photosensitive drum 41 to light to form an electrostatic latent image on the photosensitive drum 41 according to the image data. Then, the image forming unit 4 supplies toner from the development cartridge 44 to the exposed photosensitive drum 41 so that the electrostatic latent image is visualized, forming a toner image on the photosensitive drum 41.
The sheet feeding mechanism 33 in the sheet feeding unit 3 supplies a sheet S placed on the feed tray 31 to the image forming unit 4 at an appropriate timing before the toner image is formed. The image forming unit 4 conveys the sheet S supplied from the sheet feeding unit 3 between the photosensitive drum 41 and the transfer roller 45 so that the toner image supported on the photosensitive drum 41 is transferred to the sheet S. The image forming unit 4 then causes the fuser 100 to thermally fix the toner image transferred to the sheet S. The discharge unit 5 causes the discharge roller 51 to discharge the sheet S on which the toner image has been thermally fixed to the outside of the case 2 so that the sheet S is placed on the discharge tray 52.
Detailed Structure of the Fuser
The structure of the fuser 100 will be described next in detail.
As illustrated in
The endless belt 110 is an endless belt having heat resistance and flexibility. When the endless belt 110 is driven by the pressurizing roller 150, which rotates clockwise on the drawing, while in contact with it, the endless belt 110 moves forward and upward from below on a side (nip portion) on which the sheet S is held between the pressurizing roller 150 and the endless belt 110. The endless belt 110 rotates around an axial line extending in the right and left direction (width direction of the endless belt 110). The inner surface 110A of the endless belt 110 slides on the nip plate 130 and its external surface 110B faces the pressurizing roller 150. The endless belt 110 has a metal element tube made of a metal such as stainless steel. The endless belt 110 may also have a rubber layer that covers the surface of the metal element tube, and may further have a non-metal easy-to-peel material layer formed by, for example, forming a fluorine coating so as to cover the surface of the rubber layer.
The halogen lamp 120, which is separated from the nip plate 130, is a heat generating body that heats the nip plate 130 and endless belt 110 to heat toner on the sheet S. The halogen lamp 120 is placed inside the endless belt 110 at prescribed distances from the inner surfaces of the endless belt 110 and nip plate 130.
The nip plate 130 is an elongated metal plate extending in the right and left direction. It is formed by bending, for example, an aluminum plate, which has a higher heat conductivity than a stay 160, described later, made of steel. The nip plate 130 is placed so as to come into contact with the inner surface 110A of the endless belt 110. The nip plate 130 receives radiant heat from the halogen lamp 120 and transmits the received heat through the endless belt 110 to toner on the sheet S. The structure of the nip plate 130 will be described later.
The reflective plate 140 reflects radiant heat that has been emitted from the halogen lamp 120 mainly in the fore-and-aft direction and the upward direction toward the nip plate 130 (particularly, the inner surface of a base 131). The reflective plate 140 is placed inside the endless belt 110 at a prescribed distance from the halogen lamp 120 so as to enclose the halogen lamp 120.
When the radiant heat emitted from the halogen lamp 120 is collected to the nip plate 130 by the reflective plate 140 of this type, the radiant heat from the halogen lamp 120 can be used efficiently, so the nip plate 130 and endless belt 110 can be quickly heated.
The reflective plate 140 is formed by curving, for example, an aluminum plate having a large a reflection coefficient for near infrared rays and far infrared rays in a substantially U shape in a cross sectional view. To be more specific, the reflective plate 140 mainly includes a reflective part 141 having a curved shape (substantially U shape in a cross sectional view) and flanges 142, which are bent substantially perpendicularly toward the outside at both ends of the reflective part 141 and extend in the vertical direction. To increase the heat reflectivity of the reflective plate 140, it may be formed from, for example, a mirror-finished aluminum plate.
The stay 160 supports both ends of the base 131 of the nip plate 130 in the conveyance direction of the sheet S through the flanges 142 of the reflective plate 140, assuring the rigidity of the nip plate 130. The stay 160 is formed in a substantially U shape in a cross sectional view and is placed so as to cover the reflective plate 140.
The guide frame 200 supports a temperature sensor 170, which senses the temperature of the nip plate 130 to control the temperature of the fuser 100, and other parts. The guide frame 200 is secured to the stay 160. The temperature sensor 170 is disposed so as to face a temperature sensing tab 135, described later, of the nip plate 130. The temperature sensor 170 transmits, to a control unit (not illustrated), signals indicating temperatures sensed at various positions on the nip plate 130. The guide frame 200 includes guides 230 (guide members), which come into contact with the inner surface 110A of the endless belt 110 on the upstream side and downstream side of the nip plate 130.
The pressurizing roller 150 holds the endless belt 110 against the nip plate 130 of the heating member 101, drives the endless belt 110 with its rotation, and conveys the sheet S in the conveyance direction while the sheet S is being sandwiched between the pressurizing roller 150 and the endless belt 110.
In this embodiment, the nip plate 130 is placed so that its contact surface (contact portion) faces upward. Facing upward indicates not only an upward orientation in the vertical direction with respect to the gravity direction but also an upward orientation at an angle. Specifically, as illustrated in
Structure of the Nip Plate
Next, the structure of the nip plate 130 will be described in detail.
As illustrated in
The nip plate 130 is bent at the upstream end and downstream end of the base 131 in the sliding direction in which the endless belt 110 slides. As illustrated in
As illustrated in
In this embodiment, the whole downstream portion 133 functions as a wall (protrusion) with a height of h, the wall being placed so that the top end is at a position higher than the position of the bottom end. Even if the lubricant overflows from the base 131, therefore, the downstream portion 133 suppresses the lubricant from flowing out. In addition, since this wall is formed so that the inclined surface 133S continuously extends upwardly at an angle of a from the ridge 133R formed at the downstream end of the base 131 toward the downstream side, the wall returns, due to the gravity, the lubricant that is about to overflow from the downstream portion 133 to the base 131.
As described above, in this embodiment, a wall that suppresses a lubricant from flowing out can be easily formed by disposing the nip plate 130 so that its downstream portion 133 is at a distance from the endless belt 110 and by bending the nip plate 130 so that the downstream portion 133 extends upwardly at an angle, according to the orientation of the fuser 100.
In this embodiment, even if the lubricant overflows from the sliding surface 131S, that is an example of a first surface, of the nip plate 130 during the driving of the endless belt 110, it is possible to suppress the lubricant from flowing out from the inclined surface 133S of the downstream portion 133. Therefore, a problem can be efficiently avoided that, for example, the lubricant overflows from the top end 133F of the downstream portion 133, proceeds to the end surface 133E of the top end 133F and to a side surface 135S of the temperature sensing tab 135, turns back and proceeds along the rear surface 133L of the downstream portion 133, contaminates the flanges 142 of the reflective plate 140 and the outer surface 160S of the stay 160, and enters the support surface 160E of the stay 160.
The inclination (angle α with respect to a horizontal surface) of the inclined surface 133S, a difference (height h of the wall) in height between the bottom end (downstream end of the sliding surface 131S of the base 131) and the top end 133F, and a distance D from the bottom end to the top end 133F are set according to an estimated amount by which the lubricant overflows so that the effect of suppressing the lubricant from flowing out is maximized.
Specifically, the range of the distance D may be from 2.0 to 5.0 mm, 2.5 to 4.0 mm, 1.0 to 3.5 mm, or 0.5 to 3.0 mm. The range of the angle α may be 10 to 65 degrees, 15 to 50 degrees, 20 to 40 degrees, 15 to 30 degrees, or 5 to 30 degrees. When the distance D and angle α are determined in these ranges, a wall with a height h (=D sin α) can be provided at the downstream portion 133.
The wall formed at the downstream portion 133 of the nip plate 130 can take various variations. For example, as illustrated in
Specifically, the downstream portion 133 has a relief portion 133A, which extends continuously from the downstream end of the base 131 in a direction away from the inner surface 110A of the endless belt 110 and also has the inclined portion 133B, which extends continuously from the top of the relief portion 133A and is disposed so that the position of the top end is higher than the position of the bottom end.
In this embodiment as well, the wall of the downstream portion 133 is formed by bending the nip plate 130. That is, the nip plate 130 is formed in such a way that the ridge 133R is formed by bending the downstream end of the base 131 in a direction away from the inner surface 110A of the endless belt 110, the base 131 is further bent at the top of the ridge 133R toward a side opposite to the ridge 133R to form a groove 133G, and the inclined portion 133B, which is an upward slope extending from the bottom BT of the groove 133G toward the top end, is formed.
Since, in this embodiment, the downstream portion 133 has the groove 133G at a position adjacent to the downstream end of the base 131, a large capacity to retain the lubricant that has overflowed from the contact portion can be obtained. Since more lubricant that has overflowed can be retained immediately near the base 131, part of the lubricant that has been temporarily stored in the groove 133G can be efficiently collected to the endless belt 110. That is, when the inner surface 110A of the endless belt 110 comes into contact with the lubricant retained in the groove 133G due to, for example, the fluttering of the endless belt 110 during driving, the lubricant can adhere to the inner surface 110A of the endless belt 110, returning the lubricant to the contact surface.
In this embodiment as well, an effect can be expected in which the inclined surface 133S of the inclined portion 133B suppresses the lubricant that is about to overflow to the outside of the downstream portion 133 from flowing out and the lubricant is returned to the groove 133G on the upstream side.
In this embodiment, the top of the inclined portion 133B is designed so that its position is higher than the position of the ridge 133R. When the downstream end of the downstream portion 133 is formed as a protrusion extending upwardly in this way and its height h is optimized, a desired effect of suppressing the lubricant from flowing out can be obtained.
In this embodiment, even if the lubricant overflows from the sliding surface 131S during the driving of the endless belt 110, the groove 133G and inclined surface 133S of the downstream portion 133 can suppress the lubricant from flowing out from the downstream portion 133. Therefore, a problem can be efficiently avoided that, for example, the lubricant proceeds over the top end 133F of the inclined surface 133S, overflows from the end surface 133E of the top end 133F and the side surface 135S of the temperature sensing tab 135, turns back and proceeds along the rear surface 133L of the downstream portion 133, contaminates the flanges 142 of the reflective plate 140 and the outer surface 160S of the stay 160, and enters the support surface 160E of the stay 160.
The depth of the groove 133G from the ridge 133R, the inclination (angle □ with respect to a horizontal surface) of the inclined surface 133S, and a difference (height h of the wall) in height between the bottom end (bottom BT of the groove 133G) and the top end 133F are set according to an estimated amount by which the lubricant overflows so that the effect of suppressing the lubricant from flowing out and the efficiency of collecting the lubricant in the groove 133G are maximized.
Specifically, the range of the height h of the wall provided in this embodiment may be, for example, 2.0 to 6.0 mm, 1.0 to 3.0 mm, 3.0 to 4.0 mm or 0.5 to 3.0 mm.
The variation illustrated in
Since, in this embodiment, the protrusion 133C is formed at the downstream end of the downstream portion 133, it possible to more reliably suppress the overflowing lubricant from flowing out. Particularly in the form in
The direction in which the protrusion 133C extends and its height are set according to an estimated amount by which the lubricant overflows so that the effect of suppressing the lubricant from flowing out and the efficiency of collecting the lubricant in the groove 133G are maximized, together with the depth of the groove 133G from the ridge 133R, the inclination of the inclined surface 133S, and the height of its top. To suppress the lubricant from turning back at the edge of the protrusion 133C, entering the rear surface, and flowing out, the end of the protrusion 133C is placed so as not to come into contact with the inner surface 110A of the endless belt 110 during normal driving.
A variation illustrated in
In this embodiment as well, the inclined surface 133S is formed so as to continuously extend upwardly from the ridge 133R formed at the downstream end of the base 131 toward the downstream side, an effect can be expected in which the lubricant that is about to overflow from the downstream portion 133 is returned to the base 131 due to the gravity.
Furthermore, in this embodiment, since the protrusion 133C extending upwardly is formed at the downstream end of the downstream portion 133, it possible to more reliably suppress the overflowing lubricant from flowing out.
The direction in which the protrusion 133C extends and its height are set according to an estimated amount by which the lubricant overflows in consideration of the effect of suppressing the lubricant from flowing out, together with the inclination of the inclined surface 133S and the height of its top. As in the form illustrated in
So far, a typical embodiment of the present invention and its several variations have been described, but the present invention is not limited to the embodiment and variations. For specific structures, many variations can be appropriately made without departing from the intended scope of the present invention.
Although, in the above embodiment, an aspect has been exemplified in which the wall of the downstream portion 133 is positioned at a position higher than the position of the ridge 133R formed on the boundary between the base 131 and the downstream portion 133, this is not a limitation. It is also possible to position the top of the wall (end of the inclined portion 133B or end of the protrusion 133C) at a position lower than the position of the ridge 133R by forming the relief portion 133A (groove 133G) to prevent a contact with the inner surface 110A of the endless belt 110 during normal driving. Even if the base 131 faces upward in a substantially perpendicular direction, a desired effect of suppressing the lubricant from flowing out can be obtained by adjusting the depth of the groove 133G and the angle or length of the inclined portion 133B.
Although, in the above embodiment, a structure in which the downstream portion 133 includes the inclined portion 133B having the inclined surface 133S, which is substantially flat, has been described with reference to drawings, this is not a limitation. The inclined surface 133S may not be flat or the downstream portion 133 may not have the inclined surface 133S. That is, a wall (relief portion 133A) having the effect of suppressing the lubricant from flowing out can be formed by forming the groove 133G with the relief portion 133A and the protrusion 133C extending upwardly at the downstream portion 133.
Although, in the above embodiment, the halogen lamp 120 has been used as the heat source (heater) of the fuser 100 to emit radiant heat to heat the endless belt 110 through the nip plate 130 and thereby to heat toner on a sheet S, this is not a limitation to the heat source of the fuser 100. Any heat source can be used if it can directly or indirectly heat a belt. Examples of the heat source include heating bodies, such as carbon heaters and ceramic heaters, and IH heaters and other heaters that do not generate heat but can heat a metal belt, a nip plate, and the like by an electromagnetic induction heating method. The type and placement of a heat source can be appropriately selected.
The heating member 101 of the fuser 100 can also have a structure in various variations. For example, a heating member 301 illustrated in
This nip plate 330 can also achieve a desired effect of suppressing the lubricant from flowing out as the form illustrated in
Although, in the above embodiment, the walls (structural members that prevent the lubricant from flowing out) of the downstream portions 133 and 333 have been disposed across the bases 131 and 331 of the nip plates 130 and 330 in the longitudinal direction (in the direction of the rotational axis lines of the endless belts 110 and 310), this is not a limitation to the present invention. If the walls of the downstream portions 133 and 333 are disposed at least across a range corresponding to the widths of the endless belts 110 and 310, it is possible to suppress the lubricant overflowing from flowing out with the driving endless belts 110 and 310.
Although, in the above embodiment, the nip plate 130 has been exemplified as a nip forming assembly, this is not a limitation to the present invention; for example, the nip plate 130 may be formed like a block or a pad, rather than a plate. That is, although, in the above embodiment, the base 131 and downstream portion 133 have been formed by bending the nip plate 130, the contact portion of the nip forming assembly only needs to have a surface (that is, a contact portion) placed so as to come into contact with the inner surface 110A of the endless belt 110 with a lubricant intervening therebetween. The downstream portion only needs to extend from the downstream end of this contact portion and to be placed at a distance from the inner surface 110A of the endless belt 110. The nip member may be formed with a ceramic heater that doubles as the heat source described above.
Specifically, as illustrated in
Even if the guide 230 is structured in this way, the effect of suppressing the lubricant from flowing out and some other effects of the present invention can be obtained as in the form illustrated in
Although, in the above embodiment, the photosensitive drum 41 has been exemplified as the image supporting body, this is not a limitation to the present invention. For example, the image supporting body may be an intermediate transfer drum or an intermediate transfer belt that is structured so as to be capable of supporting a toner image transferred from a photosensitive drum.
Although, in the above embodiment, the sheet S, which is a thick sheet, a postcard, a thin sheet, or the like, has been exemplified as the recording sheet, this is not a limitation to the present invention. For example, the recording sheet may be an overhead projector (OHP) sheet.
Although, in the above embodiment, the laser printer 1 has been exemplified as the image forming apparatus, this is not a limitation to the present invention. For example, the image forming apparatus may be a copier, such as a flatbed scanner, or multi-function peripheral that has a document reading apparatus.
Number | Date | Country | Kind |
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2013-203247 | Sep 2013 | JP | national |