The present application claims priority to and incorporates by reference the entire contents of Japanese priority document 2008-108434 filed in Japan on Apr. 18, 2008.
1. Field of the Invention
The present invention relates to a technology related to a structure for supporting a fixing unit in an image forming apparatus.
2. Description of the Related Art
Typical electrophotographic image forming apparatuses include a photosensitive element, which is generally in the form of a belt or a drum, a developing device, an intermediate transfer member, which is generally in the form of a belt, and a fixing unit. As the photosensitive element is rotated, its surface is electrically charged and undergoes an optical writing process to have a latent image formed on the surface. The latent image is developed into a toner image by the developing device, and the toner image is transferred at a transfer position onto a recording medium, such as paper or an overhead projector (OHP) transparency, fed to the transfer position. The toner image is transferred to the recording medium directly or indirectly by way of the intermediate transfer member. The toner image is then fixed onto the recording medium in the fixing unit.
Such an image forming apparatus typically has a structure frame as a skeleton that increases rigidity against deformation and distortion. The structure frame includes a base, a pair of upright panels arranged on the base to face each other, and a stay or a bracket arranged across the upright panels. The structure frame is generally made of steel plates and detachably supports modular units in the structure frame. Examples of the modular units include a photosensitive element device, a charger device, an optical writing device, a developing device, a transfer device, a fixing device, an intermediate transfer device, and a recording-medium feed device each of which is individually formed into a modular unit. Some of these devices are combined together in some cases into a process cartridge that is also detachably supported by the structure frame.
Such an electrophotographic image forming apparatus typically includes a fixing device that causes an image formed on a recording medium to be fixed onto the recording medium while passing through a fixing nip formed between a fixing member and a pressure member. This fixing device is generally formed into a modular unit for ease of maintenance and collectively attached to and detached from the structure frame.
However, when the fixing nip in the fixing unit and a conveying roller that conveys a recording medium to the transfer position are not exactly parallel to each other, recording-medium conveying directions of the fixing unit and the conveying roller can deviate. This can disadvantageously result in skew of the recording medium or an abnormal image such as a trapezoidal image distortion. Techniques to solve these problems are disclosed in, for example, in Japanese Patent Application Laid-open No. 2004-13167, Japanese Patent Application Laid-open No. 2006-258998, and Japanese Patent Application Laid-open No. 2000-318888.
Because an image forming apparatus is constructed of a large number of components, dimensional tolerances of components can accumulate and cause a recording-medium conveying direction of a fixing unit relative to be deviated from that of a recording-medium feed device. To this end, it is conceivable to increase precision of the components; however, increasing the precision generally requires additional cost, making it less feasible. Furthermore, to ensure exact parallelism between the recording-medium conveying directions, it is necessary to reduce not only dimensional variations but also dimensional errors during assembly. However, it is practically impossible to remove dimensional errors that can occur during assembly completely.
The parallelism can be increased by using an assembly jig. However, because a high precision is required of the assembly jig in this approach, it is highly difficult to design and manufacture an assembly jig that can satisfy such a requirement. Even when such an assembly jig is used during assembly, it is practically impossible to achieve complete parallelism.
To meet growing demands for high-quality images, ensuring highly exact parallelism between recording-medium conveying devices in an image forming apparatus is required.
It is an object of the present invention to at least partially solve the problems in the conventional technology.
According to an aspect of the present invention, there is provided an image forming apparatus that includes a structure frame that includes a first upright panel and a second upright panel, the structure frame forming a skeleton of the image forming apparatus; a first unit holder that is attached to the first upright panel; a first engaging member that extends in a first direction and provided on any one of the first unit holder and the first upright panel; a second engaging member that engages with the first engaging member with substantially no play in a second direction other than the first direction and provided on other one of the first unit holder and the first upright panel; a detachable unit that is positioned and held by the first unit holder between the first upright panel and the second upright panel; and a position adjusting member that engages with the first unit holder at an engaging position and that is to be operated to move the first unit holder in the first direction relative to the structure frame for position adjustment, the engaging position being on a vertical line extending through a center of mass of the detachable unit.
According to another aspect of the present invention, there is provided a method of supporting a fixing unit in an image forming apparatus, the image forming apparatus including a structure frame that forms a skeleton of the image forming apparatus, a unit holder that positions and holds a fixing unit in the structure frame, and a position adjusting member that adjusts a position of the unit holder relative to the structure frame. The method of supporting the fixing unit includes forming a first engaging member on any one of the unit holder and the structure frame, the first engaging member extending in a first direction; forming a second engaging member on other one of the unit holder and the structure frame; bringing the second engaging member into engagement with the first engaging member with substantially no play in a second direction other than the first direction such that the unit holder is movable in the first direction relative to the structure frame for position adjustment; and arranging an eccentric cam, which is the position adjusting member, on a vertical line that extends through a center of mass of the fixing unit, the eccentric cam including a pivot shaft that is to be rotatably fitted into the structure frame into engagement therewith and an eccentric shaft that is to be rotatably fitted into the unit holder into engagement therewith.
According to still another aspect of the present invention, there is provided a method of adjusting the position of the fixing unit in the above method of supporting a fixing unit in an image forming apparatus. The method of adjusting the position of the fixing unit includes pivoting the position adjusting member to move the unit holder in the first direction relative to the structure frame.
The above and other objects, features, advantages and technical and industrial significance of this invention will be better understood by reading the following detailed description of presently preferred embodiments of the invention, when considered in connection with the accompanying drawings.
Exemplary embodiments of the present invention are described in detail below with reference to the accompanying drawings.
Although the image forming apparatus depicted in
A structure frame 40, which will be described in detail later, is a skeleton of the copier 1 and externally covered with an outer cover. The copier 1 includes an image forming unit 2, a recording-medium tray unit 3, an internal receiving tray 4, an image reading unit 5, an operation control unit 6, and a duplex unit 7. The image forming unit 2 is at a position below the image reading unit 5 and above the recording-medium tray unit 3. The image forming unit 2 forms an image and transfers the image onto a recording medium. The recording-medium tray unit 3 stores therein recording media and sequentially feeds them toward the image forming unit 2. The internal receiving tray 4 receives a recording medium on which an image has been formed. The image reading unit 5 reads an image of an original. The operation control unit 6 is arranged on a front side, as indicated by an open arrow A in
The operation control unit 6 includes an input unit and a display unit. An operator can input information related to a plurality of functions of the copier 1 from the input unit. The display unit displays various input information, states of various devices, or the like. Examples of the input unit include a start key, a numeric keypad, a function setting key, a reset key, and a clear/stop key. Examples of the output unit include a liquid crystal (LC) panel and an LC touch panel that functions also as the input unit.
The open arrow A in
The image forming unit 2 incorporates four image forming stations that form yellow (Y), cyan (C), magenta (M), and black (B) images. The image forming stations are arranged in a tandem arrangement along an intermediate transfer unit 17 that includes an intermediate transfer belt 17a which is an endless belt. An optical writing unit 13 is arranged below the four image forming stations.
Meanwhile, units being identical in configuration but different from one another only in toner color will be referred to with a reference symbol indicating the color omitted from its reference numeral in some cases. For example, the term “photosensitive drum 11” will be used below to denote an arbitrary one of photosensitive drums 11Y, 11M, 11C, and 11K. The image forming stations are identical to one another in structure and each has the photosensitive drum 11 (11Y, 11C, 11M, 11B) that is an image carrier, a charging device 12 (12Y, 12C, 12M, 12B), a developing device 14 (14Y, 14C, 14M, 14B), a primary transfer roller 15 (15Y, 15C, 15M, 15B), and a cleaning device 16 (16Y, 16C, 16M, 16B). The charging device 12, the developing device 14, the primary transfer roller 15, and the cleaning device 16 are arranged around the photosensitive drum 11.
The single optical writing unit 13 is arranged for the four image forming stations. The optical writing unit 13 includes a deflector (polygon scanner) at a center portion of the optical writing unit 13, a first optical system, four light sources for the four colors, and a second optical system. The first optical system collimates light emitted from the light sources. A laser diode (LD) is used as the light source. The deflector includes a polygon mirror (rotating polygon mirror) and a polygon motor. The second optical system includes scanning and imaging lenses, such as an fθ lens, arranged on an optical path of each of the light sources, correcting lenses, and mirrors. The optical writing unit 13 performs optical writing as follows. Laser beams are emitted from the LDs based on image data of each color. The light is deflected by the polygon scanner (deflector) so that a latent image of the corresponding color is written on the surface of each of the photosensitive drums 11Y, 11C, 11M, and 11B.
The image forming unit 2 also includes toner bottles 32Y, 32C, 32M, and 32B that are filled with yellow toner, cyan toner, magenta toner, and black toner, respectively. The toner bottles 32Y, 32C, 32M, and 32B are arranged below the internal receiving tray 4. A predetermined amount of toner is supplied from the toner bottles 32Y, 32C, 32M, and 32B to the developing devices 14Y, 14C, 14M, and 14B, respectively, through toner supply paths (not shown).
The intermediate transfer belt 17a is supported by and around a drive roller, a driven roller, and the like and rotated counterclockwise in
The recording-medium tray unit 3 includes an upper recording-medium feed cassette 3a and a lower recording-medium feed cassette 3b each of which stores therein one or more sheets of recording medium S. Recording-medium feed devices 19a and 19b and pairs of feed rollers 20a and 20b are arranged near the recording-medium feed cassettes 3a and 3b, respectively. The topmost one sheet of the recording medium S in any one of the recording-medium feed cassettes 3a and 3b is fed by the corresponding one of the recording-medium feed devices 19a and 19b to a recording-medium feed device. More specifically, the recording medium S is fed by a corresponding one of the feed rollers 20a and 20b to a pair of registration rollers 21. The registration rollers 21 then feed the recording medium S to a secondary transfer nip formed between the secondary transfer roller 22 and the intermediate transfer belt 17a with given timing.
A fixing unit 35 is arranged above the secondary transfer roller 22. The fixing unit 35 includes, for example, a fixing roller 36, a heating roller 37, a fixing belt 38, and a pressure roller 39. The fixing belt 38 is supported by and around the fixing roller 36 and the heating roller 37. A fixing nip is formed between the fixing belt 38, which is a fixing member, and the pressure roller 39, which is a pressure member.
A pair of conveying rollers 23 that conveys the recording medium S and a pair of delivery rollers 24 that delivers the recording medium S onto the internal receiving tray 4 are arranged above the fixing unit 35. A path-switching flap 25, a pair of reverse conveying rollers 26, and a reverse conveying path 27 are arranged further above the conveying rollers 23 and the delivery rollers 24. When duplex printing is selected, the path-switching flap 25 is operated to guide the recording medium S to the reverse conveying path 27. The recording medium S is temporarily stacked in the reverse conveying path 27, and then fed to the reverse conveying rollers 26 that reverse a traveling direction of the recording medium S in a switchback manner. The recording medium S is then conveyed by the pairs of conveying rollers 28 and 29 through a duplex-printing conveying path to be fed to the registration rollers 21 again.
The image reading unit 5 is arranged in an upper portion of the copier 1. The image reading unit 5 includes an exposure glass 5a, a light source 5b, a first mirror 5c, a second mirror 5d, a third mirror 5e, an imaging lens 5f, and an image sensor 5g. An original is placed on the exposure glass 5a for image reading. When the light source 5b illuminates the original, light reflected from the original is reflected by the first mirror 5c, the second mirror 5d, and the third mirror 5e to enter the imaging lens 5f. The image sensor 5g such as a charge-coupled device (CCD) is arranged at a position where an image is formed to read an image of the original. The light source 5b and the first mirror 5c are mounted on a first traveling member. The second mirror 5d and the third mirror 5e are mounted on a second traveling member.
A platen cover 33 for pressing an original placed on the exposure glass 5a is arranged on the image reading unit 5. An automatic document feeder (ADF) can be provided in place of the platen cover 33.
How the copier 1 makes a copy will be described below.
The platen cover 33 or the ADF is lifted up and an original is placed on the exposure glass 5a. When using the ADF, the original is placed on a tray of the ADF.
If the original is placed on the exposure glass 5a, the image reading unit 5 starts operation immediately after the start key on the operation control unit 6 is pressed. If the original is placed on the tray of the ADF, the image reading unit 5 starts operation after the start key is pressed and the original is fed onto the exposure glass 5a by the ADF. Thereafter, each of the first traveling member and the second traveling member is moved so that light emitted from the light source 5b is incident on the surface of the original. Light reflected from the original is then reflected by the first mirror 5c on the first traveling member, and subsequently reflected by the second mirror 5d and the third mirror 5e to be incident on the imaging lens 5f on the image sensor 5g. In this manner, an image of the original is read by the image sensor 5g. Then, image forming in any one of a full-color mode or a black-and-white mode is started according to a setting entered on the operation control unit 6. When an automatic mode is selected, the mode is automatically determined based on the acquired image.
In the image forming unit 2, the charging device 12 (12Y, 12C, 12M, 12B) uniformly charges the surface of the photosensitive drum 11 (11Y, 11C, 11M, 11B). The surface of the photosensitive drum 11 is exposed to light emitted from the optical writing unit 13 that includes the four laser light sources, the single deflector, and the four scanning optical systems. As a result, latent images are formed on the surfaces of the photosensitive drums 11Y, 11C, 11M, and 11B.
Toner of corresponding colors are caused to stick onto the latent images in the developing devices 14Y, 14C, 14M, and 14B to form yellow, cyan, magenta, and black toner images on the surfaces of the photosensitive drums 11Y, 11C, 11M, and 11B, respectively.
A primary transfer voltage is applied to the primary transfer rollers 15Y, 15C, 15M, and 15B so that the toner images on the surfaces of the photosensitive drums 11Y, 11C, 11M, and 11B are sequentially transferred onto the intermediate transfer belt 17a. The toner images are transferred onto the intermediate transfer belt 17a at a single position so that the toner images are superimposed on one another by controlling timing with which each toner image is to be transferred to the intermediate transfer belt 17a.
Timed to this primary transfer operation, feeding of the topmost one sheet of the recording medium S in any one of the recording-medium feed cassettes 3a and 3b by a corresponding one of the recording-medium feed devices 19a and 19b is performed. In a manual feeding in which the recording medium S is set in the manual feed table 8, the recording medium S is fed from the manual feed table 8 by an external-tray feed roller 30 and into the copier 1 by a pair of recording-medium feed rollers 31. In either case, when a leading end of the recording medium S reaches the registration rollers 21, a sensor (not shown) detects the recording medium S, and outputs a detection signal. The recording medium S is then fed to the secondary transfer nip formed between the secondary transfer roller 22 and the intermediate transfer belt 17a with a timing that depends on the detection signal.
The images having been primary-transferred onto the intermediate transfer belt 17a in the superimposed manner are conveyed to the secondary transfer nip where the images are collectively secondary-transferred onto the recording medium S. The recording medium S is then conveyed to the fixing unit 35 where the recording medium S passes through the fixing nip in which heat and pressure are applied to the recording medium S to fix the secondary-transferred images onto the recording medium S. The recording medium S is discharged onto the internal receiving tray 4 by the delivery rollers 24. The copier 1 forms a color image on the recording medium S in this manner.
If the duplex mode is selected on the operation control unit 6, the path-switching flap 25 is operated to guide the recording medium S, onto one side of which an image is fixed, to the reverse conveying path 27. The recording medium S is temporarily stacked in the reverse conveying path 27, and then fed to the reverse conveying rollers 26 that reverse the traveling direction of the recording medium S in the switchback manner. The recording medium S is then conveyed by the conveying rollers 28 and 29 through the duplex-printing conveying path to be fed to the registration rollers 21 again timed to the image forming process.
The registration rollers 21 feed the recording medium S again to the secondary transfer nip. At the secondary transfer nip, images formed on the intermediate transfer belt 17a are transferred onto the other side of the recording medium S. The recording medium S is then conveyed to the fixing unit 35 where the image is fixed by application of heat and pressure. The copier 1 forms color images on two sides of the recording medium S in this manner.
After residual toner on the surface of the photosensitive drum 11 (11Y, 11M, 11C, 11K) is cleaned by the cleaning device 16 (16Y, 16M, 16C, 16K), the charging device 12 (12Y, 12C, 12M, 12B) applies an alternating current (AC) superimposed on a direct current (DC) bias to the surface to discharge and charge the surface concurrently so that a new image can be formed on the surface. Residual toner on the intermediate transfer belt 17a is also cleaned by the intermediate-transfer-belt cleaning device 18.
The structure frame 40 is generally made of steel plates and includes a base 41, a first upright panel 42, a second upright panel 43, and stays (brackets) 44. The first upright panel 42 and the second upright panel 43 are arranged on the base 41 to face each other. The stays 44 are arranged across the first and second upright panels 42 and 43. The first upright panel 42 is arranged on the side, indicated by an arrow A in
The structure frame 40 detachably supports various modular units in the structure frame 40. Examples of the modular units include the photosensitive drums 11Y, 11C, 11M, and 11B, the charging devices 12Y, 12C, 12M, and 12B, the optical writing unit 13, the developing devices 14Y, 14C, 14M, and 14B, the primary transfer rollers 15Y, 15C, 15M, and 15B, the cleaning devices 16Y, 16C, 16M, and 16B, the secondary transfer roller 22, the fixing unit 35, the intermediate transfer unit 17, and the recording-medium feed device each of which is individually formed into a modular unit. Some of these units are in some cases combined together into a process cartridge that is also detachably supported by the structure frame 40.
The fixing unit 35 is positioned and held by a first unit holder 45 on the front side and a second unit holder 46 on the rear side. Because the first unit holder (hereinafter, “front unit holder”) 45 is attached to the first upright panel 42 and the second unit holder (hereinafter, “rear unit holder”) 46 is attached to the second upright panel 43, the fixing unit 35 is supported by and between the first upright panel 42 and the second upright panel 43. The arrow A in
As depicted in
The elongated hole 50 receives an eccentric shaft 53 of an eccentric cam 52 which is a position adjusting member. As depicted in
As depicted in
The eccentric shaft 53 is fitted into the elongated hole 50 into engagement therewith. A guide protrusion 61 is formed on each of an upper portion and a lower portion of the first upright panel 42. The guide protrusions 61 of the first upright panel 42 are inserted into the corresponding guide grooves 51 until the first upright panel 42 contacts the front unit holder 45. Four mount screws 63 are screwed into four screw holes defined in the first upright panel 42 through four elongated screw holes 62 (hidden in the drawings) defined in the front unit holder 45 to fix the front unit holder 45 onto the first upright panel 42.
In the first embodiment, each of the guide protrusions 61 is formed integrally with the first upright panel 42 by drawing process such as flanging. The guide protrusions 61 are positioned on a vertical line L that is parallel to a direction in which the recording medium S passes through the fixing nip. Therefore, the two guide grooves 51 of the front unit holder 45 extend in the first direction parallel to the vertical line L while the primary groove 47, the secondary groove 48, and the elongated hole 50 extend in the second direction orthogonal to the vertical line L. The elongated screw holes 62 also extend in the first direction. A line extending through the center of the pivot shaft 56 and the center of the eccentric shaft 53 is orthogonal to the vertical line L and extends in the second direction as depicted in
When the lever portion 55 is operated to cause eccentric cam 52 to pivot, the two guide protrusions 61 guide the front unit holder 45 to move in the first direction, in which the recording medium S passes through the fixing nip. The width of the guide grooves 51 is substantially identical with the diameter of the guide protrusions 61 so that each of the guide protrusions 61 is fit into a corresponding one of the guide grooves 51 with substantially no play in the second direction. This configuration prevents rattling of the guide protrusion 61 in the second direction.
It has been mentioned above that the guide grooves 51 are defined in the front unit holder 45 while the guide protrusions 61 that engage with the guide grooves 51 with no play in the second direction are formed on the first upright panel 42. Alternatively, the guide protrusions 61 can be formed on the front unit holder 45 while the guide grooves 51 are defined in the first upright panel 42. An elongated hole can be defined in place of the guide groove 51 in the first upright panel 42 or the front unit holder 45.
A fixing-unit locking lever (hereinafter, “locking lever”) 73, which has a first end and a second end, is pivotally attached at the first end to the front unit holder 45 at a position of the secondary groove 48. When the locking lever 73 is operated, the second end is moved upward as indicated by an arrow in
The rear unit holder 46 has a similar configuration to that of the front unit holder 45, and includes a primary groove 65 and a secondary groove 66. The primary groove 65 extends linearly, or in a curved manner, parallel to the secondary groove 66 that is shorter than the primary groove 65. The rear unit holder 46 is overlaid on the second upright panel 43 from the external side. A plurality of mount screws are screwed into threaded holes in the second upright panel 43 through a plurality of screw-receiving elongated holes defined in the rear unit holder 46 to fix the rear unit holder 46 onto the second upright panel 43. When the rear unit holder 46 has been fixed onto the second upright panel 43 in this manner, the primary groove 65 of the rear unit holder 46 opposes the primary groove 47 of the front unit holder 45, and the secondary groove 66 opposes the secondary groove 48. The locking lever 73 is pivotally attached at the first end to the rear unit holder 46 at a position of the secondary groove 66 such that when the locking lever 73 is operated, the second end of the locking lever 73 is moved upward. Note that this locking lever 73 is omitted from
A set of a primary reference protrusion (hereinafter, “primary protrusion”) 70 and a boss-like secondary reference protrusion (hereinafter, “secondary protrusion”) 71 protruding frontward and rearward, respectively, is formed on each of a front surface and a rear surface of the fixing unit 35. The primary protrusion 70 and the secondary protrusion 71 are spaced from each other. A grip 72 projecting upward is formed on each of a front portion and a rear portion of the top surface of the fixing unit 35. How to attach the fixing unit 35 to the copier 1 will be briefly described. The fixing unit 35 is held by the grips 72 and inserted into the copier 1 through the side door 9 on the right surface of the copier 1. By fitting the primary protrusions 70 into the primary groove 47 of the front unit holder 45 and the primary groove 65 of the rear unit holder 46 and fitting the secondary protrusions 71 into the secondary groove 48 of the front unit holder 45 and the secondary groove 66 of the rear unit holder 46, the fixing unit 35 is interposed between the front unit holder 45 and the rear unit holder 46.
When the fixing unit 35 is further inserted, the secondary protrusions 71 abut on curved surfaces 73a (see
To detach the fixing unit 35 from the copier 1, the locking levers 73 are manually pivoted to unlatch the locking levers 73 from the secondary protrusions 71. Subsequently, the fixing unit 35 is held with hands by the grips 72 and pulled frontward. While the fixing unit 35 is being pulled, the primary grooves 47 and 65 guide the primary protrusions 70 and the secondary grooves 48 and 66 guide the secondary protrusions 71.
A center (hereinafter, “gravity center”) G of the mass of the fixing unit 35 is between the upper one and the lower one of the guide protrusions 61 of the first upright panel 42. Each of the guide grooves 51 and the guide protrusions 61 are on the vertical line L that extends through the gravity center G. An engagement position between the eccentric cam 52 and the front unit holder 45, which is the position of the eccentric shaft 53, is also on the vertical line L. A line M that extends through the center of the pivot shaft 56 and the eccentric shaft 53 is orthogonal to the vertical line L.
To adjust the orientation of the fixing unit 35, the mount screws 63 and the fixing screw 59 are loosened to permit operation of the eccentric cam 52. Thereafter, the lever portion 55 is operated to cause the eccentric cam 52 to pivot about the pivot shaft 56. The orientation of the fixing unit 35 is typically adjusted such that the leading end of the lever portion 55 indicates the mark labeled with 60. More specifically, when the eccentric cam 52 is pivoted clockwise from the state depicted in
When it is determined that the fixing unit 35 is insufficiently parallel to the registration rollers 21, the fixing screw 59 and the mount screws 63 are loosened again, and the eccentric cam 52 is pivoted to adjust the position of the front unit holder 45. After the fixing screw 59 and thereafter the mount screws 63 are fastened, image forming is performed again to determine whether the fixing unit 35 is sufficiently parallel to the registration rollers 21. By repeating this procedure, vertical position adjustment of the front portion of the fixing unit 35 is performed to achieve sufficient parallelism between the fixing unit 35 and the registration rollers 21. Moving the eccentric shaft 53 in the first direction permits smooth moving of the front unit holder 45 in the first direction.
The IH-type fixing unit 35 includes a unit body 75 and an IH device 76. The IH device 76 includes a casing 84. A fixing nip is formed between a fixing roller 77, which is a fixing member, and a pressure roller 78, which is a pressure member, in the unit body 75. While a sheet of the recording medium S passes through the fixing nip, heat and pressure is applied to the recording medium S, causing an image on the recording medium S to be fixed onto the recording medium S. An IH layer is arranged on an external peripheral surface of the fixing roller 77. In this example, the fixing roller 77 is used as the fixing member; however, the fixing belt 38 as depicted in
The IH-type fixing unit 35 is similarly attached to the copier 1 such that the gravity center G of the IH-type fixing unit 35 inclusive of a heating coil 93 (magnetic-flux generating unit) is between the upper one and the lower one of the guide protrusions 61 of the first upright panel 42. Each of the guide grooves 51 and each of the guide protrusions 61 are on the vertical line L that extends through the gravity center G.
The primary protrusion 70 and the boss-like secondary protrusion 71 that are spaced from each other are formed on each of a front surface and a rear surface of the IH-type fixing unit 35. Ones of the primary protrusions 70 and the secondary protrusions 71 protrude frontward from the front surface while the other ones of the primary protrusions 70 and the secondary protrusions 71 protrude rearward from the rear surface. The grip 72 projecting upward is formed on each of the front portion and the rear portion of the top surface of the IH-type fixing unit 35. In a similar manner to that described above, to attach the IH-type fixing unit 35 to the copier 1, the IH-type fixing unit 35 is held by the grips 72 and inserted into the copier 1. The IH-type fixing unit 35 is interposed between the front unit holder 45 and the rear unit holder 46 and attached to the copier 1 in the state of being supported by the first upright panel 42 and the second upright panel 43 of the structure frame 40.
The IH-type fixing unit 35 includes a joint member 80 with which the unit body 75 and the IH device 76 are joined together.
The joint member 80 includes a bent plate 79, a positioning pin 81 that extends from the bent plate 79, and a screw receiving hole 82 defined in the bent plate 79. The joint member 80 is fixed to the unit body 75 by fastening a mount screw 83 through the screw receiving hole 82 to the unit body 75. A leading end of the positioning pin 81 is inserted into a positioning hole 85 (see
The IH device 76 has, in the casing 84, the heating coil 93 (see
Similar to the front unit holder 45 depicted in
The front unit holder 45 is attached to the first upright panel 42 from the front side. The cooling fan 90 is fitted into the fan receptacle 89 of the front unit holder 45. The front surface of the IH device 76 is urged to abut on the interior surface of the first upright panel 42 via a sealing member 92. The heating coil 93 is housed in the IH device 76. An air passage 94 is also defined in the IH device 76. The rear surface of the IH device 76 is urged to abut on the interior surface of the second upright panel 43 via a sealing member 95. The rear unit holder 46 is attached to the second upright panel 43 from the rear side. An air outlet duct 96 is connected to the rear unit holder 46.
To improve efficiency of heat generation by the fixing roller 77, the heating coil 93 is cooled while the IH device 76 is operated. More specifically, the cooling fan 90 is driven to introduce outside air through the air intake opening 88 of the front unit holder 45 into a space between the front unit holder 45 and the rear unit holder 46. This air then enters the air passage 94 through an air inlet port 97 and the through the air inlet 86 to cool the heating coil 93 in the IH device 76, and exits the air passage 94 through an air outlet 98. Subsequently, the air enters the air outlet duct 96 through-an air outlet port 99 and then through an air exit port 100 in the rear unit holder 46.
In this example, a suction fan that introduces outside air into the air passage 94 of the IH device 76 is used as the cooling fan 90. Alternatively, an exhaust fan that expels air from inside the air passage 94 can be used in place of the air suction fan. Further alternatively, both the suction fan and the exhaust fan can be used. Although the cooling fan 90 in the depicted example is an axial fan, a sirocco fan can be used.
The second IH-type fixing unit 35 that includes the IH device 76 is supported by the front unit holder 45 and the rear unit holder 46. With this configuration, when any one of the front unit holder 45 and the rear unit holder 46 is moved for position adjustment, the IH device 76 is moved together with the unit body 75. The fan receptacle 89 for holding the cooling fan 90 therein is formed on the front unit holder 45. A first air passage 102 (see
The heating coil 93 is wound inside the IH device 76 such that a coiling direction of the heating coil 93 is parallel to a width direction of a recording medium S. Opposite ends of the heating coil 93 are connected to a power supply 105 that is dedicated to the heating coil 93 and arranged outside the casing 84. When a high-frequency AC voltage is applied from the power supply 105 across the heating coil 93, the heating coil 93 in turn generates a magnetic field that causes the IH layer of the fixing roller 77 to generate heat by electromagnetic induction.
Two demagnetizing coils 106 are arranged in the casing 84 outside an area through which a sheet of the recording medium S of a minimum printable width will pass through. Note that the number of the demagnetizing coils 106 is not limited to two, and the number of the demagnetizing coils 106 arranged in the casing 84 outside the area can be three or more. The demagnetizing coils 106 are connected to an input/output (I/O) board 108 via relays 107 at positions outside the casing 84. When the recording medium S to be subjected to fixing has the minimum printable width, the I/O board 108 turns on the relays 107 to cause the heating coil 93 to generate a magnetic field and simultaneously cause the magnetic field to induce an electric current in the demagnetizing coils 106 by electromagnetic induction. The induced electric current decreases the magnetic flux generated by the heating coil 93, which reduces an electric-current-flowing area of the IH layer. Hence, a heated area on the fixing roller 77 is narrowed to meet the size of the recording medium.
When the recording medium S to be subjected to fixing has a large printable width, the I/O board 108 turns off the relays 107. In this case, because an electric current is not induced in the demagnetizing coils 106, a heated area on the fixing roller 77 is not narrowed to meet the size of the recording medium S.
The IH device 76 includes the heating coil 93 and the demagnetizing coils 106 in the casing 84. The relays 107 are mounted on a bracket 110 that is arranged outside the casing 84. Air inside the casing 84 flows in the first air passage 102 in a direction indicated by inside-hatched dotted arrows to cool the heating coil 93 and the demagnetizing coils 106. Air outside the casing 84 flows in the second air passage 103 in a direction indicated by inside-hatched solid arrows to cool the relays 107 to prevent malfunctioning of the relays 107.
When the cooling fan 90 attached in the fan receptacle 89 of the front unit holder 45 is driven, outside air is brought into the casing 84 through the first duct portion 102A. This air then collides against the heating coil 93 and the demagnetizing coils 106 to cool them while flowing through the first air passage 102, and exits the first air passage 102 on the side opposite from the first duct portion 102A. The cooling fan 90 also brings outside into the second air passage 103 through the second duct portion 103A. This air collides against the relays 107 while flowing through the second air passage 103 to cool the relays 107, and then exits the second air passage 103 on the side opposite from the second duct portion 103A.
In the state of being attached to the copier 1, the second IH-type fixing unit 35 is pressed against a stay 114 via sealing members 112 and 113. The stay 114 extends across the first upright panel 42 and the second upright panel 43. The second air passage 103 is a space enclosed by the casing 84 and the stay 114, with gaps between the casing 84 and the stay 114 sealed with the sealing members 112 and 113.
Also in the modification depicted in
Demands for less-space-consuming image forming apparatuses that fit in recent space-saving offices have increased. To meet these demands, image forming apparatuses that convey a recording medium in a portrait orientation (short edge feed) as described above have become dominant. In such an image forming apparatus, jam of a recording medium S generally occurs at a position between the registration rollers 21 and the fixing unit 35 depicted in
Meanwhile, because the fixing unit 35 contains the heating roller 37, heat is generally trapped in the fixing unit 35. The heat also heats a portion of the structure frame 40 near the fixing unit 35 and the conveying rollers 23 above the fixing unit 35. Accordingly, when removing the jammed recording medium S caught in the fixing unit 35, an operator can touch a hot surface that can result in a burn.
To this end, such a short-edge-feeding type copier as described above is typically configured as follows. The duplex unit 7 which also functions as an outer cover can be opened to permit pulling out the fixing unit 35 from the copier 1.
A structure frame with which the fixing unit 35 can be pulled out of the copier 1 and retained at a jam-removing position will be described. This structure frame is denoted by the same reference number as that of the structure frame 40 described above.
Similar to the structure frame 40 described above, the primary groove 47 and the secondary groove 48 that are defined in the front unit holder 45 as guides and extend linearly, or in a curved manner, to be parallel to each other. The primary groove 47 and the secondary groove 48 guide sliding motion of the fixing unit 35 into and out of the copier 1. The secondary groove 48 is shorter than the primary groove 47.
On the front unit holder 45 of this configuration, a small step portion 45a is arranged on a lower internal surface of the primary groove 47 at an entrance of the primary groove 47. The top surface of the step portion 45a slopes downward by a small distance toward a deep (left) end of the lower internal surface. A mount base portion 45b is arranged so as to receive a stopper 120 on a top surface of the mount base portion 45b. An insertion groove 45c that is open toward the front is arranged between an outer (right) edge of the mount base portion 45b and an edge member portion 45d. The edge member portion 45d is arranged at a further front position relative to the mount base portion 45b. A retainer-receiving groove 45e is defined in the edge member portion 45d. The retainer-receiving groove 45e, into which a retainer 121 is to be fit, is also open toward the front.
The stopper 120 is formed by bending an elongated plate into a staircase shape. The stopper 120 includes an attaching plate portion 120b in which a threaded hole 120a is defined, a mount plate portion 120c, and a stopper plate portion 120d. The mount plate portion 120c extends from an end of the attaching plate portion 120b to form the right angle therewith. The stopper plate portion 120d, which is L-shaped, extends from the mount plate portion 120c to form the right angle therewith and then extends parallel to the mount plate portion 120c. A side plate portion 120e extends downward from one side of the stopper plate portion 120d. The retainer 121 includes a knob portion 121a and a threaded portion 121b.
The stopper 120 is attached to the front unit holder 45 as follows. The attaching plate portion 120b is inserted from the front side into the insertion groove 45c such that the attaching plate portion 120b is positioned on an interior side relative to the edge member portion 45d. At this time, the mount plate portion 120c is placed on the mount base portion 45b, the stopper plate portion 120d is positioned at the entrance of the primary groove 47, and the side plate portion 120e abuts, at one side surface of its lower end portion, on the step portion 45a. By inserting the threaded portion 121b into the retainer-receiving groove 45e through the threaded hole 120a, the stopper 120 can be securely fixed to the front unit holder 45 with the retainer 121.
Similar to the configuration described above, the rear unit holder 46 is attached to the second upright panel 43. The primary groove 65 and the secondary groove 66 corresponding to the primary groove 47 and the secondary groove 48 in the above description, respectively, are defined in the rear unit holder 46. The primary groove 65 extends linearly, or in a curved manner, parallel to the secondary groove 66 that is shorter than the primary groove 65.
A small step portion 46a, which is similar but not identical with the step portion 45a, is formed on a lower internal surface of the primary groove 65 at an entrance of the primary groove 65. The top surface of the step portion 46a slopes downward by a small distance toward a deep (left) end of the lower internal surface. A mount base portion 46b is arranged so as to receive a stopper 122 on a top surface of the mount base portion 46b. An insertion groove 46c that is open toward the front is arranged between an outer (right) edge of the mount base portion 46b and an edge member portion 46d. The edge member portion 46d is arranged at a further front position relative to the mount base portion 46b. A retainer-receiving groove 46e is defined in the edge member portion 46d. The retainer-receiving groove 46e, into which a retainer 123 is to be fit, is also open toward the front.
The stopper 122, which is similar but not identical with the stopper 120, is formed by bending an elongated plate into a staircase shape. The stopper 122 includes an attaching plate portion 122b in which a threaded hole 122a is defined, a mount plate portion 122c, and a stopper plate portion 122d. The mount plate portion 122c extends from an end of the attaching plate portion 122b to form the right angle therewith. The stopper plate portion 122d extends at a small angle relative to the mount plate portion 122c and then extends parallel to the mount plate portion 122c. Side plate portions 122e extend downward from two sides, parallel to the primary groove 65, of the stopper plate portion 122d. The retainer 123 includes a knob portion 123a and a threaded portion 123b in the same manner as the retainer 121 does.
The stopper 122 is attached to the rear unit holder 46 as follows. The attaching plate portion 122b is inserted from the front side into the insertion groove 46c such that the attaching plate portion 122b is positioned on an interior side relative to the edge member portion 46d. At this time, the mount plate portion 122c is placed on the mount base portion 46b, the stopper plate portion 122d is positioned at the entrance of the primary groove 65, and the side plate portion 122e abuts, at one side surface of its lower end portion, on the step portion 46a. By inserting the threaded portion 123b into the retainer-receiving groove 46e through the threaded hole 122a, the stopper 122 can be fixed securely to the rear unit holder 46 with the retainer 123.
The fixing unit 35 includes an elongated casing 124, a recording-medium receiving port defined in a bottom surface of the elongated casing 124 (not shown), a recording-medium discharging port 125 defined in a top surface of the elongated casing 124, and grips 126. The fixing unit 35 receives a recording medium S onto which an image has been transferred through the recording-medium receiving port. One of the grips 126, which are spaced from each other, is formed on a front portion and the other is formed on a rear portion of a right surface of the elongated casing 124. As in the fixing unit 35 depicted in
The fixing unit 35 is held by the grips 126 with two hands and inserted into the copier 1 so that corresponding engaging members engage with each other. More specifically, the fixing unit 35 is inserted into the copier 1 so that the primary protrusion 70 and the secondary protrusion 71 on the front surface of the fixing unit 35 are fitted into the primary groove 47 and the secondary groove 48 in the front unit holder 45, respectively, and the primary protrusion 70 and the secondary protrusion 71 on the rear surface of the fixing unit 35 are fitted into the primary groove 65 and the secondary groove 66 in the rear unit holder 46, respectively.
As depicted in
After the fixing unit 35 is positioned in this manner, the stopper 120 is attached to the entrance of the primary groove 47 with the retainer 121 as depicted in
When the recording medium S is jammed during the course of being fed, first, the duplex unit 7 is opened as depicted in
The primary protrusion 70 on the front side is away from the stopper 120 when the fixing unit 35 is not pulled out yet (hereinafter, “stopper-away state”). On the other hand, the primary protrusion 70 on the front side abuts on the stopper plate portion 120d and the side plate portion 120e of the stopper 120 when the fixing unit 35 has been pulled out to the jam-removing position (hereinafter, “stopper-abutting state”). Although not shown, similarly, the primary protrusion 70 on the rear side of the fixing unit 35 and the stopper 122 are away from each other when the fixing unit 35 is not pulled out yet, while the primary protrusion 70 abuts on the stopper plate portion 122d and the side plate portion 122e of the stopper 122 when the fixing unit 35 has been pulled out.
In the stopper-abutting state, as depicted in
As depicted in
When the fixing unit 35 is pulled out to the stopper-abutting state where the primary protrusions 70 abut on the stoppers 120 and 122, pulling the fixing unit 35 further outward is prevented. In other words, pulling the fixing unit 35 to be detached from the copier 1 is prevented. To detach the fixing unit 35 from the copier 1, it is necessary to perform the following operation. The retainers 121 and 123 that are visible when the duplex unit 7 is open are removed to permit pulling the fixing unit 35 further outward and disengage the primary protrusions 70 and the secondary protrusions 71 from the primary grooves 47 and 65 and the secondary grooves 48 and 66, respectively.
In this example, fixation of the stoppers 120 and 122 is performed by screwing the threaded portions 121b and 123b of the retainers 121 and 123; however, fixation of the stoppers 120 and 122 can be performed by using snap-in type retainers in place of the retainers 121 and 123. It is desirable that attaching and detaching of the stoppers 120 and 122 can be performed easily without a tool.
As in the above-described example, the small step portion 45a is formed on the front unit holder 45. The mount base portion 45b that receives, on its top surface, the stopper 120 is formed. The insertion groove 45c that is open toward the front is arranged between the outer (right) edge of the mount base portion 45b and the edge member portion 45d. The edge member portion 45d is arranged at a further front position relative to the mount base portion 45b. The retainer-receiving groove 45e is defined in the edge member portion 45d. The retainer-receiving groove 45e, into which the retainer 121 is to be fit, is also open toward the front. The stopper 120 is formed by bending a metal plate in the similar manner as that of the above-described example. More specifically, the stopper 120 includes the attaching plate portion 120b in which the threaded hole 120a is defined, the mount plate portion 120c, and the stopper plate portion 120d. The mount plate portion 120c extends from an end of the attaching plate portion 120b to form the right angle therewith. The stopper plate portion 120d, which is L-shaped, extends from the mount plate portion 120c to form the right angle therewith and then extends parallel to the mount plate portion 120c. The side plate portion 120e extends downward from one side of the stopper plate portion 120d.
When it is premised that replacement of the fixing unit 35 is performed by a user, a thumb screw is used as the retainer 121. The retainer 121 includes the truncated-cone-shaped knob portion 121a, the threaded portion 121b, and an unthreaded shaft portion 121c. The threaded portion 121b axially extends from the radial center of a larger-diameter end surface of the knob portion 121a. The unthreaded shaft portion 121c coaxially extends from an end of the threaded portion 121b opposite from the knob portion 121a. The diameter of the unthreaded shaft portion 121c is smaller than the diameter of the threaded hole 120a of the stopper 120. A ring groove 121d is defined in an external surface of the unthreaded shaft portion 121c at a position close to the leading end, on the side opposite from the knob portion 121a, of the unthreaded shaft portion 121c.
As in the above-described example, the stopper 120 is attached to the front unit holder 45 as follows. The attaching plate portion 120b is inserted from the front side into the insertion groove 45c of the front unit holder 45 such that the attaching plate portion 120b is positioned on the interior side relative to the edge member portion 45d. At this time, the mount plate portion 120c is placed on the mount base portion 45b, the stopper plate portion 120d is positioned at the entrance of the primary groove 47, and the side plate portion 120e abuts, at the one side surface of its lower end portion, on the step portion 45a.
The unthreaded shaft portion 121c is inserted into the retainer-receiving groove 45e. Subsequently, the unthreaded shaft portion 121c and thereafter the threaded portion 121b are inserted into the threaded hole 120a and fastened. Hence, the front unit holder 45 is securely fixed by the retainer 121 in a state of being pinched between the stopper 120 and the retainer 121. Thereafter, a retaining member 132 such as a C-type or E-type retaining ring is fitted in the ring groove 121d to prevent accidental detaching of the retainer 121 from the stopper 120.
As depicted in
This configuration is advantageous in that even when the retainer 121 fastened to the threaded hole 120a is loosened, the unthreaded shaft portion 121c is caught by the hole base portion 120f of the attaching plate portion 120b. Put another way, the retaining member 132 prevents accidental detaching of the retainer 121 from the threaded hole 120a. In this state, it is possible to detach the stopper 120 together with the retainer 121 from the retainer-receiving groove 45e of the front unit holder 45.
This configuration is also advantageous in that the front unit holder 45 can be formed from only resin. Furthermore, the need of inserting a metal member, into which the threaded portion 121b of the retainer 121 is to be screwed, into the front unit holder 45 is eliminated. By virtue of this simple structure, the front unit holder 45 can be manufactured relatively easily and inexpensively. Eliminating the need of removing the inserted metal member from the front unit holder 45 also facilitates recycling of the front unit holder 45.
This configuration is further disadvantageous in that it is possible to select a type of the retainer 121 depending on whether replacement of the fixing unit 35 is performed by a user or a service person. When it is premised that the replacement is performed by a user, a thumb screw that is more expensive but facilitates the replacement can be used as the retainer 121. When it is premised that the replacement is performed by a service person, a relatively-inexpensive general-purpose screw can be used to avoid unnecessary additional cost.
Because the retaining member 132 prevents accidental detaching of the retainer 121 from the threaded hole 120a in the stopper 120, the retainer 121 is prevented from being lost due to carelessness of a user.
Coloring, for example, the knob portion 121a of the retainer 121, for example, green or blue as indication of a user-operable component helps a user to recognize that the user can replace the fixing unit 35 by himself/herself.
As in the stopper 120 described above, the stopper 120 according this modification is formed by bending a metal plate, and includes the attaching plate portion 120b in which the threaded hole 120a is defined, the mount plate portion 120c, and the stopper plate portion 120d. The mount plate portion 120c extends from an end of the attaching plate portion 120b to form the right angle therewith. The stopper plate portion 120d, which is L-shaped, extends from the mount plate portion 120c to form the right angle therewith and then extends parallel to the mount plate portion 120c. The side plate portion 120e extends downward from one side of the stopper plate portion 120d.
When it is premised that replacement of the fixing unit 35 is performed by a user, a thumb screw can be used as the retainer 121. The retainer 121 includes the truncated-cone-shaped knob portion 121a and the threaded portion 121b. The threaded portion 121b axially extends from the radial center of a larger-diameter end surface of the knob portion 121a. The retainer 121 includes a portion, which is also referred to as the “unthreaded shaft portion 121c”, that extends coaxially with the threaded portion 121b. The unthreaded shaft portion 121c is positioned at a substantially longitudinal center of the threaded portion 121b to divide the threaded portion 121b into a first threaded portion 121b1 and a second threaded portion 121b2.
The unthreaded shaft portion 121c can be a circular or rectangular column whose diameter or diagonal size is smaller than the diameter of the threaded hole 120a of the stopper 120. A length L3 of the unthreaded shaft portion 121c between the first threaded portion 121b1 and the second threaded portion 121b2 is larger than the thickness L1 of the stopper 120 at the hole base portion 120f where the threaded hole 120a is defined.
As in the above-described example, the stopper 120 is attached to the front unit holder 45 as follows. The attaching plate portion 120b is inserted from the front side into the insertion groove 45c such that the attaching plate portion 120b is positioned on the interior side relative to the edge member portion 45d. At this time, the mount plate portion 120c is placed on the mount base portion 45b, the stopper plate portion 120d is positioned at the entrance of the primary groove 47, and the side plate portion 120e abuts, at the one side surface of its lower end portion, on the step portion 45a. By inserting the threaded portion 121b into the retainer-receiving groove 45e through the threaded hole 120a, the stopper 120 can be securely fixed to the front unit holder 45 with the retainer 121 as depicted in
When the retainer 121 fastened to the threaded hole 120a in this manner is loosened, as depicted in
In this manner, the second threaded portion 121b2 prevents accidental detaching of the retainer 121 from the threaded hole 120a in the stopper 120. Accordingly, the retainer 121 is prevented from being lost due to carelessness of a user.
In the example depicted in
According to an aspect of the present invention, an image forming apparatus that is simple in structure and easy to assemble is provided.
Furthermore, because position adjustment of a unit holder can be performed easily by moving the unit holder, parallelism between recording-medium conveying devices can be adjusted accurately, permitting forming a high-quality image. A detachable unit can be moved for the position adjustment stably and in balance without being unintentionally inclined.
According to another aspect of the invention, serviceability of the image forming apparatus is improved because maintenance operation of the image forming apparatus to be performed by an end-user is facilitated. In addition, the maintenance operation can be performed conveniently and reliably.
According to still another aspect of the invention, a second upright panel of a structure frame of the image forming apparatus can be manufactured relatively easily and inexpensively by constructing a second unit holder that supports the detachable unit separately from the second upright panel.
According to still another aspect of the invention, a first engaging member can be formed relatively inexpensively. In addition, when attaching the unit holder to a first upright panel, an operator can visually check how the first engaging member and the second engaging member engage with each other through an opening in any one of the first engaging member and the second engaging member. This improves operability.
According to still another aspect of the invention, because only a vertical load is applied on the unit holder, the unit holder can be moved in a first (vertical) direction smoothly.
According to still another aspect of the invention, parallelism between a fixing nip of a fixing unit and a conveying roller of a recording-medium feed device can be adjusted accurately by using a position adjusting member. This prevents skew of a recording medium or an abnormal image such as a trapezoidal image distortion, causing quality of an image to be improved.
According to still another aspect of the invention, the unit holder is moved by the position adjusting member only in a direction in which the recording medium passes through the fixing nip. This permits the parallelism between the conveying roller and the fixing nip to be achieved more accurately, causing quality of an image to be further improved.
According to still another aspect of the invention, because a fixing member does not include a heat source, the fixing member is prevented from being burnt due to waste heat of the heat source. A fire that would otherwise be caused by a recording medium that is sticking to and around the fixing member and accidentally comes into contact with the heat source is also prevented. From another point of view, because additional protecting means against these burning and fire is not required, it is possible to avoid undesirable increase in complexity, size, and cost.
According to still another aspect of the invention, because a heating width of the fixing member can be adjusted depending on a size of a recording medium, it is possible to prevent end portions of the fixing member from being heated to high temperature.
According to still another aspect of the invention, because an IH device is cooled during operation of the IH device, reduction in efficiency of heat generation by an IH layer in the fixing device due to heat from an energized heating coil can be prevented.
According to still another aspect of the invention, because a distance between a unit body of the fixing unit and the IH device is kept constant, the IH layer can generate heat efficiently without fail.
According to still another aspect of the invention, during operation of the IH device, a cooling device cools the heating coil and a relay by causing air to flow efficiently such that one of air flows passes inside a casing of the IH device and the other one passes outside the same. Accordingly, reduction in efficiency in heat generation by the IH layer and malfunctioning of the relay are prevented.
According to still another aspect of the invention, an air flow path can be formed without adding a dedicated duct member. This leads to cost reduction.
According to still another aspect of the invention, it is possible to select a suction fan as a cooling fan of the cooling device depending on a thermal condition inside the casing of the IH device or the image forming apparatus.
According to still another aspect of the invention, it is possible to select an exhaust fan as the cooling fan depending on a thermal condition inside the casing or the image forming apparatus.
According to still another aspect of the invention, the IH device can be cooled more efficiently by introducing and exhausting air with the cooling fans.
According to still another aspect of the invention, position of the unit holder can be finely adjusted by pivoting the position adjusting member.
According to still another aspect of the invention, the unit holder can be moved smoothly by aligning a moving direction of an eccentric shaft of the position adjusting member with a direction in which the unit holder is moved.
According to still another aspect of the invention, because the fixing unit is prevented from unintentionally being pulled out from the image forming apparatus, an inconvenience of returning the fixing unit having been unintentionally pulled out back into the image forming apparatus would not occur. Furthermore, because an external surface of the image forming apparatus does not partially obstruct removal of a jammed recording medium, the jammed recording medium can be removed easily and safely without fear of touching hot surfaces of the fixing unit, a portion of a structure frame, a recording-medium conveying unit, a conveying roller, and the like.
According to still another aspect of the invention, a distance between an installed position of the fixing unit and a jam-removing position at which a jammed recording medium is to be removed from the fixing unit is relatively short. This facilitates removal of a jammed recording medium.
According to still another aspect of the invention, the fixing unit can be pulled out to the jam-removing position more easily.
According to still another aspect of the invention, it is possible to reliably block the fixing unit that has been pulled out to the jam-removing position from further traveling outward with a simple configuration. Accordingly, an inconvenience of returning the fixing unit that has been unintentionally pulled out back into the image forming apparatus would not occur.
According to still another aspect of the invention, a stopper and a protrusion are less easily deformed by abutting on each other. Accordingly, the stopper and the protrusion are relatively resistant to impacts that can be imparted on the stopper and the protrusion when the fixing unit is pulled out with a relatively large force.
According to still another aspect of the invention, because an operator can detach a retainer from the stopper easily, the fixing unit can be pulled out easily.
According to still another aspect of the invention, because the retainer can be detached from the stopper easily, the fixing unit can be pulled out easily.
According to still another aspect of the invention, the unit holder can be formed only from resin. Furthermore, the need of inserting a metal member into the unit holder is eliminated. By virtue of this simple structure, the unit holder can be manufactured relatively easily and inexpensively. Eliminating the need of removing the inserted metal member from the unit holder also facilitates recycling of the unit holder.
According to still another aspect of the invention, one of different types of the retainer can be used depending on whether replacement of the fixing unit is performed by a user or a service person. Accordingly, it is possible to facilitate the replacement when it is performed by the user and to avoid unnecessary additional cost when the replacement is performed by a service person.
According to still another aspect of the invention, it is more recognizable to a user that the user can replace the fixing unit by himself/herself.
According to still another aspect of the invention, even when the retainer is loosened, accidental detaching of the retainer from a threaded hole in the stopper is prevented. Accordingly, the retainer is prevented from being lost due to carelessness of a user.
Although the invention has been described with respect to specific embodiments for a complete and clear disclosure, the appended claims are not to be thus limited but are to be construed as embodying all modifications and alternative constructions that may occur to one skilled in the art that fairly fall within the basic teaching herein set forth.
Number | Date | Country | Kind |
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2008-108434 | Apr 2008 | JP | national |