Patent Grant
9037024
The present application claims priority under 35 U.S.C. §119 to Japanese Patent Application No. 2012-097361, filed Apr. 23, 2012. The contents of this application are incorporated herein by reference in their entirety.
The present disclosure relates to fusing devices for fusing unfused toner images to a recording medium by inserting and passing the recording medium carrying the unfused toner images into and through a fusing nip formed by a belt and a roller which are pressed against and made contact with each other, and thereby applying heat and pressure to the recording medium, and to image forming apparatuses including such a fusing device.
In conventional image forming apparatuses, toner images formed on an image carrier, such as a photoconductive drum or the like, are transferred to a recording medium. The recording medium carrying the toner images is conveyed toward a fusing device. The fusing device fuses the toner images to the recording medium by applying heat and pressure thereto. Among fusing devices is a belt fusing device. The belt fusing device fuses unfused toner images to a recording medium by inserting and passing the recording medium carrying the unfused toner image into and through a fusing nip. The fusing nip is formed by an endless fusing belt heated and a pressure roller. The fusing belt is pressed against and made contact with the pressure roller.
In the belt fusing device, a pressing member is provided inside the fusing belt, and the pressure roller is pressed against the pressing member from the outside of the fusing belt. Also, in the belt fusing device, the fusing belt is driven to rotate while sliding on the pressing member with the inner surface of the fusing belt being in contact with the pressing member. Also, in the belt fusing device, the surface of the pressing member on which the fusing belt slides has a flat or arc-shaped surface to provide a wide nip width, whereby fusing performance and recording medium releasability are improved.
However, if the pressing member has the arc-shaped sliding surface, then when unfused toner images are fused to a recording medium, such as an envelope or the like, the front and back sides of the envelope have different conveyance speeds at the fusing nip, so that the front and back sides of the envelope are wrinkled, or the flap of the envelope is not correctly placed at a predetermined position (flap misalignment).
There is a known conventional technique of preventing or reducing the formation of wrinkles and the like on an envelope during the fusing process. For example, some fusing devices include a pressing member including a soft pad of an elastic soft material and a hard pad of a hard material, and a switching mechanism which can switch the fusing device between a normal mode in which fusing is performed on plain paper, such as A4 paper and the like, and an envelope mode. In the normal mode, the soft and hard pads are pressed against and made contact with the fusing belt, whereby a fusing nip is formed. On the other hand, in the envelope mode, the hard pad is separated by the switching mechanism, so that only the soft pad is pressed against and made contact with the fusing belt, whereby a fusing nip is formed. As a result, the nip pressure is reduced, and therefore, wrinkles and flap misalignment of the envelope are reduced.
According to a first aspect of the present disclosure, a fusing device fuses an unfused toner image formed on a recording medium, to the recording medium. The fusing device includes a regulating member and a switching mechanism. The regulating member has a flat surface and an arc-shaped surface and regulates a nip formed by an endless belt and a roller. The switching mechanism switches the fusing device between a first mode and a second mode in which the unfused toner image is fused to the recording medium. The flat surface is provided along a direction in which the recording medium enters the nip. The arc-shaped surface is provided downstream of the flat surface in the recording medium entry direction, is contiguous to the flat surface, and is curved toward the roller. In the first mode, the nip is regulated by the flat surface and the arc-shaped surface. In the second mode, the nip is regulated by the flat surface of the flat and arc-shaped surfaces.
According to a second aspect of the present disclosure, an image forming apparatus includes an image forming unit and a fusing device. The image forming unit forms a toner image on a recording medium. A fusing device fuses an unfused toner image formed on a recording medium, to the recording medium. The fusing device includes a regulating member and a switching mechanism. The regulating member has a flat surface and an arc-shaped surface and regulates a nip formed by an endless belt and a roller. The switching mechanism switches the fusing device between a first mode and a second mode in which the unfused toner image is fused to the recording medium. The flat surface is provided along a direction in which the recording medium enters the nip. The arc-shaped surface is provided downstream of the flat surface in the recording medium entry direction, is contiguous to the flat surface, and is curved toward the roller. In the first mode, the nip is regulated by the flat surface and the arc-shaped surface. In the second mode, the nip is regulated by the flat surface of the flat and arc-shaped surfaces.
Embodiments of the present disclosure will be described hereinafter with reference to the accompanying drawings. The present disclosure is not intended to be limited to these embodiments. Applications described herein are exemplary in nature and are not intended to be an exhaustive list. Terms used herein are not intended to be limited to any particular narrow interpretation unless clearly stated otherwise, either expressly or impliedly, in this document. In the drawings, like parts are indicated by like reference characters and will not be redundantly described.
The paper feed unit 2 includes a plurality of paper feed cassettes 7 for holding paper 9 (recording medium), and a manual feed tray 22 for manually supplying paper. The paper 9 is fed out on a sheet by sheet basis by rotation of a feed roller 8 from a selected one of the paper feed cassettes 7 to the paper conveyance unit 3. A recording medium, such as paper having a size different from that of the paper 9 held in the paper feed cassettes 7, an envelope, and an OHP transparency, is placed on the manual feed tray 22. The manual feed tray 22 feeds out the recording medium placed thereon to the paper conveyance unit 3.
The paper 9 fed to the paper conveyance unit 3 is conveyed on a paper conveyance path 10 toward the image forming unit 4. The image forming unit 4 forms a toner image on the paper 9 by an electrophotographic process. To do so, the image forming unit 4 includes a photoconductive body 11 which is supported for rotation in a direction indicated by an arrow in
The charging unit 12 includes a charging wire to which a high voltage is applied. When a surface of the photoconductive body 11 is caused to have a predetermined potential by corona discharge generated by the charging wire, the surface of the photoconductive body 11 is uniformly charged. Thereafter, when the surface of the photoconductive body 11 is irradiated by the exposing unit 13 with light which is generated based on image data of an original document which has been read by the image reading unit 6, the potential of the surface of the photoconductive body 11 is selectively lowered, so that an electrostatic latent image is formed on the surface of the photoconductive body 11.
Next, the developing unit 14 develops the electrostatic latent image on the surface of the photoconductive body 11 to form a toner image on the surface of the photoconductive body 11. The toner image is transferred by the transfer unit 15 to the paper 9 supplied between the photoconductive body 11 and the transfer unit 15.
The paper 9 having the transferred toner image is conveyed toward the fusing device 5, which is located downstream of the image forming unit 4 in the paper conveyance direction. The fusing device 5 applies heat and pressure to the paper 9 so that the toner image is melted and fused to the paper 9. Next, the paper 9 having the fused toner image is exited to an exit tray 21 by an exit roller pair 20.
After the toner image has been transferred to the paper 9 by the transfer unit 15, the toner remaining on the surface of the photoconductive body 11 is removed by the cleaning unit 16. Also, residual charge is removed from the surface of the photoconductive body 11 by the charge neutralizing unit 17. Thereafter, the photoconductive body 11 is charged again by the charging unit 12 so that image formation will subsequently be similarly performed.
The fusing device 5 has a configuration shown in
The fusing device 5 employs a fusing technique which utilizes induction heating. The fusing device 5 includes a fusing belt 26, a pressure roller 19, an induction heating unit 30 for heating the fusing belt 26, thermistors 25 as a temperature detecting unit, and a belt support member 55.
The fusing belt 26 is an endless heat-resistant belt. The fusing belt 26 is formed by successively stacking an induction heating layer 26a, an elastic layer 26b, and the release layer 26c from the inner circumferential side. The induction heating layer 26a is formed, for example, of electroformed nickel having a thickness of 30-50 μm. The elastic layer 26b is formed, for example, of silicone rubber having a thickness of 100-500 μm. The release layer 26c is formed, for example, of a fluorocarbon resin having a thickness of 30-50 μm, and is used to improve the releasability of the fusing belt 26 when an unfused toner image is melted and fused to a recording medium at a fusing nip N. Note that the induction heating layer 26a may be formed, for example, of a polyimide resin having a thickness of 50-100 μm which contains metal powder of copper, silver, aluminum, or the like.
The belt support member 55 has a guide portion 59 and a pad holding portion 56, and is formed of a metal (aluminum etc.), a heat-resistant resin, etc. The guide portion 59 is in the shape of an arc as viewed in cross section. The guide portion 59 holds the fusing belt 26 with the fusing belt 26 being separated from the induction heating unit 30 by a predetermined space. The pad holding portion 56 holds a pressing pad 60 which is a pressing member (regulating member). The pressing pad 60 is provided on an inner circumferential surface of the fusing belt 26, facing the pressure roller 19 with the fusing belt 26 being interposed between the pressing pad 60 and the pressure roller 19. The pressing pad 60 presses the fusing belt 26 against the pressure roller 19. Note that the pad holding portion 56 may be separated from the guide portion 59. In this case, for example, the pad holding portion 56 is supported by the apparatus body.
The pressure roller 19 includes a cylindrical cored bar 19a of stainless steel or the like, an elastic layer 19b of silicone rubber or the like formed on the cored bar 19a, and a release layer 19c of a fluorocarbon resin or the like covering a surface of the elastic layer 19b. The pressure roller 19 is driven to rotate by a drive source (not shown), such as a motor or the like. The fusing belt 26 is rotated by rotation of the pressure roller 19. The fusing belt 26 is pressed against the pressure roller 19 so that the fusing nip N is formed at a portion where the pressure roller 19 and the fusing belt 26 are in contact with each other. At the fusing nip N, heat and pressure are applied to the unfused toner image on the paper 9 conveyed so that the toner image is fused to the paper 9.
The induction heating unit 30 includes a coil 37, a bobbin 38, and a magnetic core 39. As a result, the induction heating unit 30 heats the fusing belt 26 by electromagnetic induction. The induction heating unit 30 is arranged to face the fusing belt 26, extending in a width direction (a direction perpendicular to the drawing sheet of
The excitation coil 37 is a loop of Litz wire wound several times along the width direction (the direction perpendicular to the drawing sheet of
The thermistors 25 are provided at a predetermined height from the outer surface of the fusing belt 26, facing a middle portion and opposite end portions in the width direction of the fusing belt 26. The thermistors 25 detect temperatures of the middle portion and the opposite end portions. A current supplied to the excitation coil 37 of the induction heating unit 30 is controlled based on the temperatures detected by the thermistors 25.
The fusing belt 26 is heated by the induction heating unit 30 which is heating means (heating unit). The paper 9 held in the fusing nip N is heated by the fusing belt 26 and pressed by the pressure roller 19. As a result, the toner powder is melted and fused to the paper 9 at a temperature which allows fusing. After the fusing process, the paper 9 is conveyed while being tightly attached to the surface of the fusing belt 26, and thereafter, is released from the surface of the fusing belt 26 by a separation member (not shown), and is conveyed downstream of the fusing device 5.
The pressing pad 60 is formed of a heat-resistant resin, such as a liquid crystal polymer resin or the like, or an elastic material, such as silicone rubber or the like. The pressing pad 60 may include an elastomer at a sliding surface 60a which faces the fusing belt 26. In order to reduce the sliding load of a contact surface between the sliding surface 60a and the fusing belt 26, a sliding member (not shown) of a fluorocarbon resin, such as a polytetrafluoroethylene (PTFE) sheet or the like, may be interposed between the sliding surface 60a and the fusing belt 26. When the pressing pad 60 is formed of a liquid crystal polymer resin, deformation of the pressing pad 60 due to heat and pressure applied thereto is prevented or reduced, whereby the shape of the fusing nip N can be maintained unchanged over a long period of time.
The sliding surface 60a of the pressing pad 60 has a flat portion 61 (flat surface) which is generally parallel to the paper conveyance direction on an upstream side of the fusing nip N (a direction indicated by arrow A in
The arc-shaped portion 63 has a larger radius of curvature than that of an outer circumferential surface of the pressure roller 19. This configuration allows the pressing force (nip pressure) of the fusing nip N to become lower toward from upstream to downstream in the paper conveyance direction. Therefore, the pressing pad 60 is less likely to deform due to heat of the fusing belt 26 and pressure of the pressure roller 19. As a result, the releasability of the downstream end portion of the fusing nip N with respect to the paper 9 can be maintained over a long period of time.
In this embodiment, a first mode and a second mode are provided, and the fusing device 5 can be switched between the two modes. In the first mode, the pressure roller 19 is pressed against the flat portion 61 and the arc-shaped portion 63 with the fusing belt 26 being interposed between the pressure roller 19, and the flat portion 61 and the arc-shaped portion 63, to form the fusing nip N. In other words, in the first mode, the flat portion 61 and the arc-shaped portion 63 regulate the fusing nip N. In the second mode, the pressure roller 19 is pressed against only the flat portion 61 (i.e., of the flat portion 61 and the arc-shaped portion 63, the flat portion 61) with the fusing belt 26 being interposed between the pressure roller 19 and the flat portion 61, to form the fusing nip N. In other words, in the second mode, of the flat portion 61 and the arc-shaped portion 63, the flat portion 61 regulates the fusing nip N.
When the fusing process is performed on plain paper, such as A4 paper or the like, the pressure roller 19 is pressed against the flat portion 61 and the arc-shaped portion 63 by a predetermined pressure with the fusing belt 26 being interposed between the pressure roller 19, and the flat portion 61 and the arc-shaped portion 63 (first mode). In this configuration, the flat portion 61 and the arc-shaped portion 63 are successively and contiguously arranged from upstream in the paper conveyance direction to form the fusing nip N. Therefore, the paper 9 entering the fusing nip N firstly passes the flat portion 61 and then the arc-shaped portion 63. Therefore, the paper 9 can be stably inserted into the fusing nip N. When the paper 9 passes the arc-shaped portion 63, the toner has already been melted and fused to the paper 9 to some extent. As a result, the fused image is less likely to be disturbed when the paper 9 passes the arc-shaped portion 63 where nip pressure is likely to vary, and therefore, stable fusing performance can be provided.
On the other hand, when the fusing process is performed on a recording medium, such as an envelope or the like, the pressure roller 19 is pressed against only the flat portion 61 (i.e., of the flat portion 61 and the arc-shaped portion 63, the flat portion 61) by a predetermined pressure with the fusing belt 26 being interposed between the pressure roller 19 and the flat portion 61 (second mode). In this configuration, the fusing nip N becomes flat to provide a predetermined nip pressure, and a width (fusing nip width) across which the pressing pad 60 and the pressure roller 19 are in contact with each other is relatively short. Therefore, when a recording medium, such as an envelope or the like, passes through the fusing nip N, the front and back sides of the envelope have the same conveyance speed, and the nip pressure applied to the envelope is generally reduced. As a result, wrinkles and/or flap misalignment of the envelope can be reduced.
As shown in
The pair of holding plates 71 are provided at both ends of the support shaft of the pressure roller 19, and are each a generally rectangular, flat plate. A pressure roller holding portion 71a which is a U-shaped oblong hole is provided at an upper edge portion of each holding plate 71. The pressure roller holding portions 71a rotatably hold the support shaft of the pressure roller 19. A guide hole 71b which is an oblong hole extending in the paper conveyance direction A is formed at a left edge portion (an upstream side in the paper conveyance direction (paper entry direction) A) of each holding plate 71. A guide pin 67 is fixed to each side plate 65, which is a member of the body of the fusing device 5. The guide pin 67 is fitted in the guide hole 71b. Therefore, the holding plate 71 is held for movement along the guide hole 71b in the paper conveyance direction A, i.e., in a direction generally parallel to the flat portion 61 (see
A front pressure spring 66, such as a tension coil spring or the like, is provided between a right edge portion (a downstream side in the paper conveyance direction A) of the front holding plate 71 and the front side plate 65. Similarly, a back pressure spring 66 is provided between a right edge portion (a downstream side in the paper conveyance direction A) of the back holding plate 71 and the back side plate 65. The holding plate 71 is biased upward in
The front spring member 72 for biasing the front holding plate 71 to the downstream side in the paper conveyance direction A is provided at a left edge portion of the front holding plate 71. Similarly, the back spring member 72 for biasing the back holding plate 71 to the downstream side in the paper conveyance direction A is provided at a left edge portion of the back holding plate 71. The front cam plate 73 is provided in the vicinity of a right edge portion of the front holding plate 71. Similarly, the back cam plate 73 is provided in the vicinity of a right edge portion of the back holding plate 71. The cam plate 73 is mounted to the apparatus body (not shown) for rotation about a rotating shaft 73a. The cam plate 73 has a circular outer edge portion which is pressed against and made contact with a cam contact surface 71c which is formed at a right edge portion of the holding plate 71. The rotating shaft 73a is located away from the center of the circle of the cam plate 73. When the rotating shaft 73a is rotated by a drive source (not shown), such as a motor or the like, the eccentric cam plate 73 is also rotated. When the cam plate 73 is rotated by 180 degrees about the rotating shaft 73a, the holding plate 71 performs a leftward translational movement in
In the second mode of
When the fusing device 5 is switched from the second mode to the first mode, the cam plate 73 is rotated by 180 degrees about the rotating shaft 73a. Thus, when the eccentric cam plate 73 is rotated, the holding plate 71 is moved by the biasing force of the spring member 72 along the guide hole 71b to the downstream side in the paper conveyance direction A, resulting in the state of the fusing device 5 shown in
As described above, the switching mechanism 70 reciprocally moves the pressure roller 19 in the paper entry direction A and in the direction opposite to the paper entry direction A, to switch the fusing device 5 between the first mode and the second mode. Specifically, the switching mechanism 70 moves the pressure roller 19 in the direction opposite to the paper entry direction A to switch the fusing device 5 from the first mode to the second mode. On the other hand, the switching mechanism 70 moves the pressure roller 19 in the paper entry direction A to switch the fusing device 5 from the second mode to the first mode. Note that the holding plates 71 hold the pressure roller 19 so that the pressure roller 19 can move in the paper entry direction A and in the direction opposite to the paper entry direction A.
Although, in the above embodiment, the spring member 72 biases the holding plate 71 to the downstream side in the paper conveyance direction A so that the cam plate 73 is invariably pressed against and made contact with the cam contact surface 71c at the right edge portion of the holding plate 71, the present disclosure is not limited to this. For example, the spring member 72 may bias the holding plate 71 to the upstream side in the paper conveyance direction A and the cam contact surface 71c may be provided at a left edge portion of the holding plate 71 so that the cam plate 73 is invariably pressed against and made contact with the cam contact surface 71c (first variation). Thus, in the first embodiment and the first variation described with respect to
Alternatively, for example, the spring member 72 may bias the holding plate 71 in the paper conveyance direction A so that, in one of the first and second modes, the holding plate 71 is pressed against and made contact with the apparatus body, and is thereby held at a predetermined first position, and in the other mode, the holding plate 71 is pressed against and made contact with the cam plate 73, and is thereby held at a predetermined second position (second variation). The first and second variations have advantages similar to those of the embodiment described with reference to
As shown in
The pair of holding plates 71 are provided at both ends of the support shaft of the pressure roller 19, and has a generally rectangular, flat shape. Each holding plate 71 has a fitting hole 71d for rotatably holding the support shaft of the pressure roller 19. A rotation support hole 71e is provided at an upper portion of a left edge of each holding plate 71. A support shaft 68 which is fixed to the side plate 65 is fitted in the rotation support hole 71e so that the holding plate 71 can rotate. Here, the support shaft 68 shown is provided in the front side plate 65. The rotation support hole 71e is provided at a position which is located upstream of a fusing nip N in a paper conveyance direction (paper entry direction) A, and is closer to the pressing pad 60 than to the center O of rotation of the pressure roller 19. Because of the position of the rotation support hole 71e (pivot), when the holding plate 71 is rotated clockwise (in a direction indicated by arrow C) about the support shaft 68, the pressure roller 19 is rotated clockwise (in the direction indicated by arrow C) about the support shaft 68. In other words, the pressure roller 19 moves downward in
A front pressure spring 66, such as a tension coil spring or the like, is provided between a right edge portion (on a downstream side in the paper conveyance direction A) of the front holding plate 71 and the front side plate 65. Similarly, a back pressure spring 66 is provided between a right edge portion (on a downstream side in the paper conveyance direction A) of the back holding plate 71 and the back side plate 65. The holding plate 71 is biased upward in
The front cam plate 73 is provided at an upper edge portion of the front holding plate 71 in the vicinity of the front pressure spring 66. Similarly, the back cam plate 73 is provided at an upper edge portion of the back holding plate 71 in the vicinity of the back pressure spring 66. The front cam plate 73 is attached to the front side plate 65 for rotation about the front rotating shaft 73a. Similarly, the back cam plate 73 is attached to the back side plate 65 for rotation about the back rotating shaft 73a. The cam plate 73 has a circular outer edge portion. The cam plate 73 is configured to allow the outer edge portion of the cam plate 73 to be made contact with and separated from a cam contact surface 71c which is formed at an upper edge portion of the holding plate 71. In the state (first mode) of
In the second mode of
When the fusing device 5 is switched from the second mode to the first mode, the cam plate 73 is rotated by 180 degrees about the rotating shaft 73a. As a result, the cam plate 73 is separated from the cam contact surface 71c of the holding plate 71, and the holding plate 71 is rotated anticlockwise about the support shaft 68 by the biasing force of the pressure spring 66, resulting in the state of
Note that, as described with reference to
Note that the present disclosure is not intended to be limited to the first and second embodiments. Various changes and modifications can be made without departing the scope and spirit of the present disclosure. For example, the present disclosure is intended to cover the following variations.
(1) Although, in the first and second embodiments, the induction heating unit 30 is employed as heating means, the present disclosure is not limited to this. For example, the heating means may be a halogen lamp or the like.
(2) Although the fusing belt 26 is heated in the fusing device 5 described with reference to
As described above, according to the embodiments of the present disclosure, when the fusing process is performed on a recording medium, such as plain paper (e.g., A4 paper) or the like, the switching mechanism switches the fusing device to the first mode so that the fusing nip is formed in a flat shape and in an arc-shaped shape. As a result, an unfused toner image on the recording medium is consistently satisfactorily fused. On the other hand, when the fusing process is performed on a recording medium, such as an envelope or the like, the switching mechanism switches the fusing device to the second mode so that the fusing nip is formed in a flat shape. As a result, wrinkles (e.g., wrinkles of an envelope) and/or flap misalignment (e.g., flap misalignment of an envelope) of the recording medium are reduced, and therefore, an unfused toner image on the recording medium is satisfactorily fused.
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