The present document incorporates by reference the entire contents of Japanese priority documents, 2005-269743 filed in Japan on Sep. 16, 2005, 2006-193639 filed in Japan on Jul. 14, 2006 and 2006-218770 filed in Japan on Aug. 10, 2006.
1. Field of the Invention
The present invention relates to a transferring apparatus that transfers a visible image formed on an image carrier onto a recording medium and fixes the image to the recording medium. The present invention also relates to an image forming apparatus using the transferring apparatus.
2. Description of the Related Art
There has been known an image forming apparatus that, after transferring a visible image such as a toner image formed on an image carrier to a recording sheet such as transfer paper, feeds the recording sheet into a fixing apparatus to fix the visible image. In this type of image forming apparatus, an unfixed visible image could be disturbed due to a contact of an image carrier surface to the recording sheet around an inlet, a guide plate, or the like of a fixing apparatus, when the recording sheet is to be fed into the fixing apparatus while the visible image transferred is yet unfixed.
On the other hand, there has been known an image forming apparatus where transferring processing and fixing processing of a visible image to a recording sheet are substantially and simultaneously performed by a transfer/fixing apparatus (for example, see Japanese Patent Application Laid-open No. 2004-145260). A transfer/fixing apparatus in this type of image forming apparatus includes a transfer member, a nip forming member that are endlessly moved while surfaces thereof are contacting with each other, and a heating unit that heats a visible image. After a visible image, which is carried on such an image carrier as an intermediate transfer member, is transferred on a surface of a transfer member, the visible image advances to a transfer fixing nip formed by contacting portions of two surfaces of endless moving members, while the visible image is heated by the heating unit. A recording sheet is fed into the transfer fixing nip in synchronization with the advancing of the visible image. The visible image on the surface of the transfer member is fixed on the fed-in recording sheet while being transferred thereon. With this configuration, transferring processing and fixing processing of the visible image to the recording sheet are substantially and simultaneously performed in the transfer fixing nip in the transfer/fixing apparatus. Thereby, after the visible image is transferred on the recording sheet, the recording sheet is conveyed so that the visible image fixed. Therefore, this configuration can avoid a problem such that the unfixed visible image is disturbed due to rubbing the image against a guide plate or the like.
However, since it is necessary to heat a visible image on a surface of a first endless moving member prior to advancing to a nip, the transfer/fixing apparatus tends to have a larger heat loss amount than a fixing apparatus that performs fixing processing only in a nip. Therefore, it is desired that the heat loss be reduced as much as possible.
The present invention has been achieved in view of these circumstances, and an object of the invention is to provide a transferring apparatus and an image forming apparatus as described below. That is, the object is to provide a transferring apparatus that avoids a problem such that an unfixed image is disturbed due to rubbing of the image against a guide plate or the like, and can further reduce a heat loss amount as compared with former transfer fixing apparatus, and the like.
It is an object of the present invention to at least partially solve the problems in the conventional technology.
According to one aspect of the present invention, a transferring apparatus that receives a visible image carried on an image carrier, and transfers the image to a recording medium includes a transfer member configured to receive toner corresponding to the image from the image carrier; a heating unit that heats the transfer member having the image thereon thereby heating the toner on the transfer image; a nip-forming member configured to form a nip between the transfer member, and sandwich a recording medium in the nip thereby transferring hot toner from the transfer member to the recording medium for transferring the image from the transfer member onto the recording medium; and a first guide member and a second guide member that guide the recording medium toward the nip, the first guide member and the second guide member being arranged so as to form a substantial V-shape with tip of the V-shape being toward the nip, and a distance between the first guide member and the second guide member at the tip being equal to or less than 5 millimeters.
According to another aspect of the present invention, a transferring apparatus that receives a visible image carried on an image carrier, and transfers the image to a recording medium includes a transfer member configured to receive toner corresponding to the image from the image carrier; a heating unit that heats the transfer member having the image thereon thereby heating the toner on the transfer image; a nip-forming member configured to form a nip between the transfer member, and sandwich a recording medium in the nip thereby transferring hot toner from the transfer member to the recording medium for transferring the image from the transfer member onto the recording medium; and a covering member that covers an inlet side of the nip and is provided with an opening through which the recording medium advances toward the nip, the opening having a first length that is wider than width of the recording medium and a second length that is equal to or less than 5 millimeters.
According to still another aspect of the present invention, an image forming apparatus includes the above transferring apparatus.
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 according to the present invention will be explained below.
A basic configuration of the printer will be first explained.
As shown in
As shown in
A paper feed cassette 50, which accommodates a plurality of sheets of transfer paper P that is recording members in a stacking manner where the sheets of transfer paper P are stacked, is disposed below the intermediate transfer belt 11 shown in
An intermediate transfer unit 10 that endlessly moves the intermediate transfer belt 11 that is an intermediate transfer member and is an image carrier while spanning the same is disposed below the process units 6Y, 6M, 6C, and 6K shown in
The four first transfer bias-rollers 12Y, 12M, 12C, and 12K sandwich the intermediate transfer belt 11 endlessly moved between them and the photoconductors 1Y, 1M, 1C, and 1K to form a first transfer nips. While the first transfer bias-rollers adopt a system for applying transfer biases with a polarity reverse (for example, a plus polarity) to that of the toners to a back face (the loop inner circumferential face) of the intermediate transfer belt 11, so as to configure a charge system for performing discharge from electrodes.
In a process that the intermediate transfer belt 11 sequentially passes through the first transfer nips for Y, M, C, and K due to an endless movement thereof, the Y, M, C, and K toner images on the photoconductors 1Y, 1M, 1C, and 1K are primarily transferred on the intermediate transfer belt 11 in superimposition with one another. Thereby, a four-color superimposed toner image (hereinafter, “four-color toner image”) is formed on the intermediate transfer belt 11.
A transfer/fixing apparatus 20 including a transfer fixing roller 21 and the like is disposed on the right side of the intermediate transfer unit 10 shown in
The four-color toner image formed on the front face of the intermediate transfer belt 11 according to passage thereof trough the four first transfer nips advances in the second transfer nip according to endless movement of the intermediate transfer belt 11. The four-color toner image is secondarily transferred collectively from the front face of the intermediate transfer belt 11 to a surface of the transfer fixing roller 21 under second transfer field and nip pressure. At this time, toner forming the four-color toner image is softened due to heating from the transfer fixing roller 21 so that adherence of the toner to the transfer fixing roller 21 with the surface coarser than the belt surface is increased. Accordingly, the second transfer is improved.
A plurality of patch-like belt marks (not shown) made from a material favorable in light reflectivity such as aluminum is fixed on one end portion of the intermediate transfer belt 11 in a belt width direction over a whole circumference of the belt at a predetermined pitch. The belt marks are detected by a belt mark sensor 18 that is a reflection type photo-sensor arranged to face the surface of the intermediate transfer belt 11 that has passed through the second transfer nip via a predetermined gap.
The endless movement speed of the intermediate transfer belt 11 varies slightly due to the eccentricity of a drive-transmission gear or thickness deviation of the belt even if the intermediate transfer belt 11 is rotated at a constant speed by a drive motor serving as a drive source for the drive roller 13. When the intermediate transfer belt 11 is endlessly moved at a constant speed, the mark detection interval obtained by the belt mark sensor 18 becomes a predetermined time interval. However, when speed fluctuation of the intermediate transfer belt 11 occurs, the mark detection interval varies. The printer includes a belt speed control circuit (not shown), and'the belt speed control circuit detects speed fluctuation of the intermediate transfer belt 11 based on an output signal from the belt mark sensor 18 to feed back the detection result to the drive speed of the drive motor. Thereby, the speed fluctuation of the intermediate transfer belt 11 is suppressed.
A cooling device 17 including a heat pipe 17a, a cleaning blade 17b, and the like is disposed on the left side of the belt mark sensor 18 shown in
The belt cleaning device 16 is disposed to sandwich the intermediate transfer belt 11 between the same and the cleaning backup roller 15 on the left side of the intermediate transfer belt 11 shown in
Besides the transfer fixing roller 21, the transfer/fixing apparatus 20 includes a halogen lamp 22, a reflecting plate 23, a pressurizing roller 24, a cleaning roller 25, a first guide plate 26, a second guide plate 27, a casing 28 that is a housing, and the like.
The transfer fixing roller 21 includes a cored bar 21a made from metal such as aluminum and an adiabatic layer 21b made from a hard material such as porous ceramic or glass and formed on a surface of the cored bar 21a. The transfer fixing roller 21 also includes an elastic layer 21c with a thickness of 0.05 to 0.5 millimeter made from an elastic material such as silicon rubber, that is formed on a surface of the adiabatic layer 21b, and a surface layer (not shown) with a thickness of 10 to 30 micrometers made from a fluorine resin material such as perfluoroalkoxy polymer resin (PFA) or polytetrafluoroethylene (PTFE) coated on a surface of the elastic layer. The surface layer made from a fluorine resin material is formed on the surface of the elastic layer 21c by material coating or thermal shrinkage of tube material, and it develops favorable releasing performance to toner adhered on the surface layer. It is preferable that the cored bar 21a has a thickness or a diameter equal to or less than 1 millimeter for shortening a temperature-rising time. It is also preferable that heat conductivity of the adiabatic layer 21b is set equal to or less than 0.1 W/mK, and compression strength thereof is set equal to or more than 3 megapascal for achieving both of high adiabatic performance and compression strength enduring load acting on a transfer fixing nip described later. It is preferable that the elastic layer 21c has a thickness of equal to or more than 0.1 millimeter for securing a fixed surface layer universal hardness, and it is also preferable that the elastic layer 21c has a thickness equal to or less than 0.5 millimeter for shortening the temperature-rising time. It is preferable that the surface layer has a thickness equal to or less than 30 micrometers for securing a fixed surface layer universal hardness. A circumferential length of the transfer fixing roller 21 is set to be larger than a length of transfer paper P with the maximum size (A3 in this example) that can be accommodated in the paper feed cassette 50.
A heating unit including the halogen lamp 22 and the reflecting plate 23 is disposed below the transfer fixing roller 21 shown in
A surface temperature sensor (not shown) that detects a surface temperature of the transfer fixing roller 21 utilizing a well-known technique is disposed inside the transfer/fixing apparatus 20 to output a temperature signal to a heater power source circuit (not shown). The heater power source circuit turns ON and OFF of power supplying to the halogen lamp 22 based on the temperature signal from the surface temperature sensor. Thereby, the surface temperature of the transfer fixing roller 21 is maintained in a fixed temperature range.
The transfer fixing roller 21 that is a transfer member is rotationally driven in a counterclockwise direction shown in
The pressurizing roller 24 is arranged on the right side of the transfer fixing roller 21 shown in
As shown in
In the transfer fixing nip, toner contained in the softened four-color toner image causes toner positioned on the surface side of the toner layer to bite in between fibers of the transfer paper P. Thereby, the four-color toner image is fixed on the transfer paper P. The transfer fixing roller 21 and the transfer paper P separate from each other at the outlet of the transfer fixing nip. However, since the transfer paper P has the surface coarser than that of the fixing roller 21, adhesion of the four-color toner image to the transfer paper P is made higher than that to the transfer fixing roller 21. Therefore, the four-color toner image on the transfer fixing roller 21 is thirdly transferred on the transfer paper P. When favorable third transfer cannot be achieved by utilizing only a different in surface coarseness between the paper and the roller, electrostatic transfer is used together with utilization of the different in the third transfer for assisting the third transfer. In this case, when a material including a dispersed conductive material such as a carbon material is used for each layer on the cored bars in the transfer fixing roller 21 and the pressurizing roller 24, the cored bar of one of the rollers 21 and 24 can be grounded while that of the other is applied with transfer bias.
As shown in
In the printer with the basic configuration described above, the visible image forming unit that forms a toner image that is a visible image on the surface of the intermediate transfer belt 11 serving as the image carrier includes the optical write unit 7, the four process units 6Y, 6M, 6C, and 6K, and the intermediate transfer unit 10.
Next, the characteristic configuration of the printer will be explained.
The receiving opening 28b is formed in the casing 28 so as to face downwardly in a vertical direction, and transfer paper fed from the registration roller pair disposed below the transfer/fixing apparatus 20 is received in the casing 28 through the receiving opening 28b. A first holder member 30 is fixed on an edge portion of a peripheral edge portion of the receiving opening 28b that is positioned on the left side shown in
The first guide plate 26 and the second guide plate 27 are arranged between the transfer fixing nip and the receiving opening 28b. The first guide plate 26 and the second guide plate 27 that are positioned such that temperatures thereof are easily raised by radiation from the heating unit include flexible thin plates made from metal a material such as copper or aluminum as base members therefor. A surface of the base member is coated with a surface layer made from a low frictional material such as fluorine resin for making sliding between the guide plate and transfer paper smooth. One end of the first guide plate 26 positioned on the opening side is cantilevered by the first holder member 30, while a free end thereof that is positioned on the nip side is positioned near the transfer fixing nip. One end of the second guide plate 27 positioned on the opening side in an aspect where the second guide plate 27 faces the first guide plate 26 is cantilevered by the second holder member 31, while a free end thereof that is positioned on the nip side is caused to contact with the free end of the first guide plate 26. While the first guide plate 26 and the second guide plate 27 are closing the receiving opening 28b by causing the free ends to contact with each other, they guide transfer paper that is a recording sheet and advances in between both of the guide plates toward the transfer fixing nip.
Rising air current easily occurs due to heat generated by the halogen lamp 22 inside the transfer/fixing apparatus 20. While the receiving opening 28b facing downwardly in the vertical direction remains opened, external air is actively taken in from the receiving opening 28b into the casing 28 to accelerate rising air current. Heated air within the casing 28 is actively released from the surface-exposing opening 28a or the discharging opening 28c positioned above the receiving opening 28b in the vertical direction, so that heat-retention performance is largely reduced. However, as shown in
A leading edge of transfer paper conveyed while guided by the first guide plate 26 and the second guide plate 27 soon abuts on the contacting portion between both of the plates to advance in between the plates. The transfer paper P pushes the free ends of the first guide plate 26 and the second guide plate 27 to separate them from each other. The respective free ends of the first guide plate 26 and the second guide plate 27 that are then flexible are flexed outwardly in directions in which they do not approach to each other but separate from each other. According to the flexing, both of the guide plates separate from each other and the transfer paper advances in between both of the guide plates, so that the transfer paper is guided toward the transfer fixing nip in the casing 28, as shown in
The guide plate 105 is thus fixed on the edge portion of the receiving opening 101a positioned on the right side shown in
On the other hand, in the transfer/fixing apparatus 20 in the printer, as shown in
As shown in
As described above, in the transfer fixing nip, when both of a heating-transfer system and an electrostatic transfer system are used, one of the transfer fixing roller 21 and the pressurizing roller 24 is grounded while the other thereof is applied with third transfer bias. With this configuration, as shown in
In the printer, plates having contacting faces with transfer paper P whose sizes in a direction perpendicular to the sheet conveying direction, namely, sizes thereof in a direction perpendicular to the figure paper plane, satisfy the following condition are used as the first guide plate 26 and the second guide plate 27. That is, the condition is that the sizes are larger than a size of transfer paper P with the maximum size (A3 size in the embodiment) that can be accommodated in the paper feed cassette 50 in a direction perpendicular to the conveying direction. With this configuration, even if transfer paper P with the maximum size is used, the transfer paper P can be reliably guided toward the transfer fixing nip by the first guide plate 26 and the second guide plate 27.
With regard to a layout in the printer, it is preferable that the discharging opening 28c of the casing 28 faces upwardly in the vertical direction, as shown in
It has been known that a shape of toner particles forming a toner image is related to transfer performance (transfer efficiency or maintenance of image shape) of a toner image from the intermediate transfer belt 11 to the transfer fixing roller 21. Toner where the Wadell's practical sphericity φ of the toner particle is equal to or more than 0.8 is favorable in transfer performance. Therefore, toner where the Wadell's practical sphericity φ of the toner particle is equal to or more than 0.8 is used as the toner in the present embodiment. The Wadell's practical sphericity φ can be measured utilizing a method disclosed in Japanese Patent Application Laid-open No. H09-258474. Specifically, the Wadell's practical sphericity φ can be obtained by using such a relational equation as “φ=(a diameter L1 of a circle equal to a particle projection area)/(a diameter L2 of a circle circumscribed on a particle projection image). Powdered toner is placed on a slide glass in a proper amount, it is observed by a microscope of 500 magnifications, and the above-described L1 and L2 of any 100 toner particles in the powdered toner are measured, so that the Wadell's practical sphericity φ is obtained. Toner powder where an average value of the Wadell's practical sphericities φ of 100 toner particles is equal to or more than 0.8 is used.
The example that plates which are flexible and have free ends caused to contact with each other are used the first guide plate 26 and the second guide plate 27 has been explained. However, plates which are non-flexible and have free ends facing each other via a gap equal to or less than 5 millimeters can be used as the guide plates.
In the printer, a covering member that covers an inlet of the transfer fixing nip is formed by a bottom plate of the casing 28 of the transfer/fixing apparatus 20, and the first guide plate 26 and the second guide plate 27 that are fixed to the bottom plate. A gap between the first guide plate 26 and the second guide plate 27 functions as an opening for guiding transfer paper P into the transfer fixing nip.
In the first modified apparatus 20A thus configured, a movement distance of the transfer member (the transfer fixing roller 21 or the transfer fixing belt 41) from an outlet of the transfer fixing nip to the second transfer nip is elongated by using the transfer fixing belt instead of the transfer fixing roller 21. Thereby, the transfer member is advanced into the second transfer nip after being further cooled. Heat conduction from the transfer member to the intermediate transfer belt 11 is suppressed so that thermal degradation of the intermediate transfer belt 11 can be suppressed. When the transfer fixing roller 21 is used, heat from the halogen lamp 22 is transferred to the cored bar in the roller, however, when a transfer fixing belt unit is used, heat conduction to the cored bar can be suppressed. Thereby, an accumulated heat quality is reduced so that energy efficiency can be raised.
A shutter member 35 that opens and closes the discharging opening 28c according to rotation thereof around a rotation shaft 36 is provided on an upper wall of the casing 28. The rotation shaft 36 is rotated via drive transmission (not shown) including a gear and the like, so that the shutter member 35 is rotated to open or close the discharging opening 28c. One of the three openings 28a, 28b, and 28c provided in the casing 28 that releases heat inside the casing 28 most easily is the discharging opening 28c provided in the upper wall of the casing 28. Therefore, the shutter member 35 is provided to suppress wasteful leakage hot air from the discharging opening 28c as much as possible. Thereby, only when the transfer paper P is discharged from the discharging opening 28c, the discharging opening 28c is opened, or the discharging opening 28c is continuously opened during continuous paper discharging in a continuous printing operation, so that heat loss can be largely reduced. When heat remains excessively due to closing of the shutter member 35, control for opening the shutter member 35 periodically at a timing except for paper discharging can be performed by a shutter operation control unit. Thereby, dew condensation in the casing 28 due to excessive remaining of heat can be avoided. The shutter member 35 can adopt a configuration where opening and closing operations are performed according to slide thereof instead of the configuration where the operations are performed according to rotation thereof.
Next, a printer according to a second embodiment of the present invention will be explained. A basic configuration of the printer according to the second embodiment is similar to that of the printer according to the first embodiment unless otherwise specified, and explanation thereof is omitted. As shown in
With this configuration, by setting the gap between the first guide plate 26 and the second guide plate 27 to a small size such as equal to or less than 5 millimeters, which has not been set, an advancing amount to the opening 29a of air current occurring according to conveyance of transfer paper at an upstream side of the shielding plate 29 that is a covering member in the transfer paper conveying direction can be reduced. Thereby, a problem such that hot air remaining around the halogen lamp 22 is blown away by air current that advances from the opening 29a is avoided, so that a heat loss amount can be reduced.
Next, a printer a according to a third embodiment of the present invention will be explained. A basic configuration of the printer according to the third embodiment is similar to that of the printer according to the first embodiment unless otherwise specified, and explanation thereof is omitted. As shown in
Since the first guide plate 26 is positioned near a heating unit including the halogen lamp 22, the reflecting plate 23, and the like, the plate is heated by the heating unit. A temperature of the first guide plate 26 varies according to a distance from the heating unit to the first guide plate 26, a shape of the reflecting plate 23, and the like, and it can reach about 100° C. The paper feed path 51 is configured to feed transfer paper toward the first guide plate 26 thus heated by the heating unit. Specifically, the paper feed path 51 is for causing transfer paper to pass between a first path plate 51a disposed on the left side shown in
The first guide plate 26 and the second guide plate 27 are each formed by coating a thin plate made from metal having high heat conductivity such as copper or aluminum with heat-stable resin such as polyimide. By thickening the first guide plate according to application of the resin coating, a heat accumulation amount of the first guide plate 26 is increased so that it is made possible to utilize the accumulated heat quality for preheating efficiently. However, flexibility of the guide plate cannot be developed sufficiently due to its thickening. Therefore, the first guide plate 26 and the second guide plate 27 are attached to be rotatable about rotation shafts 26a and 27a, and the free ends of both of the plates are biased by forces such as spring forces such that the plates approach to each other. When transfer paper advances in between both of the plates, the free ends of the plates are rotated in directions opposed to biasing directions of the spring forces. Opening and closing of the receiving opening according to displacement of the free ends can be accomplished.
When both of the heating-transfer system and the electrostatic transfer system are used in the transfer fixing nip, it is preferable that plates formed with a surface layer made from insulating material are used as the first guide plate 26 and the second guide plate 27 so that the leakage of current to the guide plates is prevented. It is preferable that the surface layer of the first guide plate 26 is formed from material with low frictional coefficient regardless of simultaneous use of the electrostatic transfer system. Thereby, stacking of transfer paper on the first guide plate 26 can be avoided by smoothly sliding a leading edge of the transfer paper pushed on the first guide plate 26 in the paper feed path 51 on a surface of the first guide plate 26.
A printer according to a fourth embodiment of the present invention will be explained next. A basic configuration of the printer according to the fourth embodiment is similar to that of the printer according to the first embodiment unless otherwise specified, and explanation thereof is omitted. As shown in
The opening 28d of the casing 28 is formed in a rectangular shape, and a short side of the opening 28d is shown so as to face the front shown in
A pre-reception first guide plate 53 and a pre-reception second guide plate 54 serving as pre-reception guide members that guide a recording sheet fed from the registration roller pair before it is received in the opening 28d toward the opening 28d are arranged between a registration roller pair (not shown) and the opening 28d of the casing 28 serving as a covering member that covers an inlet of the transfer fixing nip. Transfer paper fed from the registration roller pair (not shown) advances in between the two guide plates. The pre-reception first guide plate 53 contacts with an image transfer face of the transfer paper to guide the transfer paper from one end of the short side of the opening 28d toward a central portion thereof. The pre-reception second guide plate 54 contacts with a back face of the transfer paper opposite to the image transfer face to guide the transfer paper from the other end of the short side of the opening 28d toward the central portion.
A spacing distance on the opening 28d side between the pre-reception first guide plate 53 and the pre-reception second guide plate 54 is narrower than a spacing distance on the registration roller side therebetween. Therefore, after transfer paper fed from the registration roller is received between both of the guide plates on the registration roller side where the spacing distance is relatively long, the transfer paper gradually approaches to the central side of the short side of the opening 28d while being guided toward the opening 28d side where the spacing distance is relatively short.
It is preferable that the spacing distance on the opening 28d side between both of the guide plates 53 and 54 is set to be slightly shorter than the length W of the opening 28d in the short side direction. With this configuration, stacking of a leading edge of transfer paper on a periphery of the opening 28d can be avoided. However, even if the configuration is adopted, the length W of the discharging opening 28c in the short side direction is made remarkably short, there is a possibility that the leading edge of the transfer paper is trapped by the inner wall of the opening 28d. While in the present printer, the length W is set equal to or less than 5 millimeters, preferably equal to or less than 2 millimeters, the length W is set to be longer than a size where stacking of a leading edge of transfer paper on the inner wall of the opening 28d is likely to happen exponentially according to inclination angles of both of the guide plates 53 and 54. A desirable value (the lower limit value of the length W) of the size varies according to the inclination angles of both of the guide plates 53 and 54.
The first inlet shutter-sheet 81 is cantilevered by a casing portion of a periphery of the opening 28d that is continuous to one end of the opening 28d in the short side direction of the opening, so that a free end thereof can be flexed. As shown in
The second inlet shutter-sheet 82 is cantilevered by a casing portion of the periphery of the opening 28d that is continuous to the other end of the opening 28d in the short side direction of the opening, so that a free end thereof can be flexed. The free end closes an opening region that is not closed by the first inlet shutter-sheet 81, as shown in
The inlet shutter-sheets close a whole region of the opening 28d by causing the free ends to contact with each other at a central portion of the opening.
When transfer paper P is fed from a registration roller pair (not shown) to the opening 28d, as shown in
With this configuration, when transfer paper P is not fed into the casing 28, the opening 28d is closed by the inlet shutter-sheets, so that heat loss in the transfer/fixing apparatus can be reduced as compared with a case that the opening 28d is always opened. Even if a drive unit that drives the inlet shutter members is not provided, the opening 28d can be opened and closed by moving two inlet shutter-sheets that are the inlet shutter members for opening and closing the opening 28d.
The example where the casing 28 including the opening 28d is provided as the covering member that covers the transfer fixing nip inlet has been explained, however, the casing is not required to cover the whole transfer/fixing apparatus necessarily. The covering member can cover at least the transfer fixing nip inlet and the heating unit.
With this configuration, by setting the gap of the opening 29a in the short side direction to a short size such as equal to or less than 5 millimeters, which has not been set, an advancing amount to the opening 29a of air current occurring according to conveyance of transfer paper at an upstream side of the shielding plate 29 that is a covering member in the transfer paper conveying direction can be reduced. Thereby, a problem such that hot air remaining around the halogen lamp 22 is blown away by air current advancing from the opening 29a is avoided, so that a heat loss amount can be reduced.
A printer according to a fifth embodiment of the present invention will be explained next. A basic configuration of the printer according to the fifth embodiment is similar to that of the printer according to the first embodiment unless otherwise specified, and explanation thereof is omitted. As shown in
The first guide plate 26 extends such that a free end thereof gradually approaches from the long side inner wall of the opening 28d cantilever-supporting the first guide plate 26 towards the other long side inner wall, and the free end approaches closest to the other long side inner wall. A gap W between a portion (the free end in the shown example) of the first guide plate 26 positioned nearest the other long side inner wall and the other long side inner wall is set equal to or less than 5 millimeters.
With this configuration, by setting the gap W between the first guide plate 26 and the long side inner wall of the opening 28d to a short size such as equal to or less than 5 millimeters, which has not been set, an amount of air current sucked from the gap into the casing is suppressed, so that a heat loss amount in the transfer/fixing apparatus 20 can be reduced.
When a flexible member flexed according to the contact with transfer paper is used as the first guide plate 26, 0 millimeter, which is included in the range of equal to or less than 5 millimeters, can be adopted as the gap W.
With this configuration, by setting the gap W between the first guide plate 26 and the long side inner wall of the opening 29a to a small size such as equal to or less than 5 millimeters, which has not been set, an advancing amount to the opening 29a of air current occurring according to conveyance of transfer paper at an upstream side of the shielding plate 29 that is a covering member in the transfer paper conveying direction can be reduced. Thereby, a problem such that hot air remaining around the halogen lamp 22 is blown away by air current advancing from the opening 29a is avoided, so that a heat loss amount can be reduced.
The printer where the second transfer nip that is the contacting portion between the intermediate transfer belt 11 and the transfer fixing nip 22 is formed just beside the transfer fixing nip 21 has been heretofore explained. However, the present invention is applicable to a printer with other configurations. For example, the second transfer nip can be disposed obliquely upward of, obliquely downward of, just above, or just below the transfer fixing nip. As described shown in FIG. 1 in Japanese Patent Application Laid-open No. 2004-145260, the transfer fixing nip can be disposed obliquely. The free transfer belt system as described shown in FIGS. 5 and 6 in Japanese Patent Application Laid-open No. 2004-145260, the pressurizing belt system shown in FIGS. 8 and 9 in Japanese Patent Application Laid-open No. 2004-145260, or the transfer fixing belt system as described shown in FIGS. 10 and 11 in Japanese Patent Application Laid-open No. 2004-145260 can be adopted.
The example where the present invention is applied to the printer of the electro-photographic system has been heretofore explained. However, the present invention is applicable to an image forming apparatus forming an image utilizing a direct recording system. The direct recording system is a system that directly forms a toner image on a recording medium or member or an intermediate recording member by causing toner groups flied from a toner flying device in a dot manner to directly adhere on the recording member or the intermediate recording member to form a pixel image. The direct recording system has been adopted in an image forming apparatus described in Japanese Patent Application Laid-open No. 2002-307737 and the like.
In the apparatuses shown in
In the apparatuses shown in
In the apparatus shown in
In the fourth modified apparatus in the transfer/fixing apparatus of the printer according to the first embodiment, as shown in
In the printer according to the third embodiment, as shown in
In the apparatuses shown in
In the printers and the respective modified apparatus according to respective embodiments, since the layout that the discharging opening of the casing 28 is directed upwardly in the vertical direction is adopted, dew condensation due to remaining excessive heat in the casing 28 can be suppressed by the above reasons.
In the first embodiment, since toner having Wadell's practical sphericity equal to or more than 0.8 is used as toner for forming a toner image, images with high quality can be formed, without any disturbance caused during transfer.
In the embodiment of the present invention, by substantially simultaneously performing transferring processing and fixing processing of a visible image to a recording sheet in the transfer/fixing apparatus, the recording sheet fixed with the visible image is conveyed after the visible image has been transferred on the recording sheet. Therefore, a problem such that an unfixed visible image is disturbed due to rubbing against a guide plate or the like can be avoided.
According to the embodiment of the present invention, by setting the gap between the first guide plate and the second plate to a short size such as equal to or less than 5 millimeters, which has not been adopted, an advancing amount to the transfer/fixing apparatus of air current occurring according conveyance of a recording sheet can be reduced. Accordingly, a heat loss amount due to the advancing of air current can be reduced.
According to the embodiment of the present invention, by setting the length of the opening in the covering member in a short side direction thereof to a short size such as equal to or less than 5 millimeters, which has not been adopted, an advancing amount to the opening of air current occurring at an upstream side of the covering member in a conveying direction of the recording sheet according to conveyance of a recording sheet can be reduced. Accordingly, a problem such that hot air remaining around the heating unit is blown away by air current advancing from the opening is avoided, so that a heat loss amount due to the advancing of air current can be reduced.
According to the embodiment of the present invention, by setting the gap between the inner wall of the opening of the covering member and the guide member that guides a recording sheet advanced into the opening to a short size such as equal to or less than 5 millimeters, which has not been adopted, an advancing amount of air current occurring at an upstream side of the covering member in a direction of the recording sheet conveyance according to conveyance of a recording sheet can be reduced. Accordingly, a problem such that hot air remaining around the heating unit is blown away according to air current entering from the opening is avoided, so that a heat loss amount due to entrance of air current can be reduced.
Preferably, the embodiment of the present invention provides a transfer/fixing apparatus that includes a transfer member that transfers a visible image carried on an image carrier to an endlessly moving surface of the transfer member, a heating unit that heats the visible image transferred on the surface of the transfer member, and a nip forming member that causes an endless moving surface thereof to contact with the surface of the transfer member to form a nip between both of the surfaces, where the visible image on the surface of the transfer member is fixed on a recording sheet nipped in the nip while being transferred on the recording sheet, where the transfer member, the heating unit, and the nip forming member are covered with a casing including a surface-exposing opening that exposes a portion of a surface of the transfer member to cause the portion to face the image carrier, a receiving opening that receives the recording sheet fed from the outside to guide the same to the nip, a discharging opening that discharges the recording sheet discharged from the nip to the outside, and a guide unit that guides the recording sheet received from the receiving opening toward the nip, and the guide unit is structured that, while the receiving opening is closed by causing a first guide member whose end portion positioned on the side of the receiving opening is cantilevered by a peripheral edge of the receiving opening between the receiving opening and the nip and a second guide member fixed to the peripheral edge of the receiving opening so as to face the first guide member to contact with each other, the recording sheet advanced in between both of the guide members is guided toward the nip, and the receiving opening is opened by displacing a free end of the first guide member according to contact with the recording sheet to separate the first guide member from the second guide member.
Preferably, the embodiment of the present invention provides a transfer/fixing apparatus that includes a transfer member that transfers a visible image carried on an image carrier to an endlessly moving surface of the transfer member, a heating unit that heats the visible image transferred on the surface of the transfer member, and a nip forming member that causes an endless moving surface thereof to contact with the surface of the transfer member to form a nip between both of the surfaces, where the visible image on the surface of the transfer member is fixed on a recording sheet nipped in the nip while being transferred on the recording sheet, where the transfer member, the heating unit, and the nip forming member are covered with a casing including a surface-exposing opening that exposes a portion of a surface of the transfer member to cause the portion to face the image carrier, a receiving opening that receives the recording sheet fed from the outside to guide the same to the nip, a discharging opening that discharges the recording sheet discharged from the nip to the outside, and a guide unit that guides the recording sheet received from the receiving opening toward the nip, and the guide unit is structured that, while an opening size of the receiving opening is narrowed to a size of a gap of equal to or less than 250 micrometers by a first guide member whose end portion positioned on the side of the receiving opening is cantilevered by a peripheral edge of the receiving opening between the receiving opening and the nip and a second guide member fixed to the peripheral edge of the receiving opening so as to face the first guide member with each other via the gap of equal to or less than 250 micrometers, the recording sheet that advances in between both of the guide members is guided toward the nip, and the size of the receiving opening is further enlarged by displacing a free end of the first guide member according to contact with the recording sheet.
In these configurations, by covering the first endlessly moving member, the heating unit, and the second endlessly moving member to cause heat from the heating unit to remain in the casing, the heat loss amount in the transfer/fixing apparatus can be reduced as compared with the transfer fixing apparatus. The receiving opening in the casing is closed by contact between the first guide member and the second guide member or it is opened by such a minute amount as equal to or less 250 micrometers, which corresponds to a thickness of an ordinary cardboard, while a recording sheet is not fed into the transfer/fixing apparatus. Accordingly, by suppressing ventilation from the inside of the casing to the outside thereof via the receiving opening or suppressing ventilation from the receiving opening to the outside of the casing via the inside of the casing and the surface-exposing opening or the discharging opening, the heat loss amount in the transfer/fixing apparatus can be further reduced.
The embodiment of the present invention can provide an image forming apparatus that includes an image carrier that carries a visible image on a surface thereof, a visible image forming unit that forms a visible image on the image carrier, a transfer/fixing apparatus that fixes the visible image on a recording sheet while transferring the visible image from the image carrier to the recording sheet, and a sheet supply path that supplies a recording sheet to the transfer/fixing apparatus, where the transfer/fixing apparatus includes a transfer member that transfers a visible image carried on the image carrier to an endlessly moving surface of the transfer member, a heating unit that heats the visible image transferred on the surface of the transfer member, and a nip forming member that causes an endless moving surface thereof to contact with the surface of the transfer member to form a nip between both of the surfaces, where the visible image on the surface of the transfer member is fixed on a recording sheet nipped in the nip while being transferred on the recording sheet, where a guide member that is disposed at a position to be heated by the heating unit and guides the recording sheet fed from the sheet supply path toward the nip while contacting with the recording sheet is provided in the transfer/fixing apparatus, and the sheet supply path is configured so as to feed the recording sheet positioned inside the sheet supply path toward the guide member. In this configuration, prior to advancing of a recording sheet fed from the sheet supply path toward the transfer/fixing apparatus into the nip in the transfer/fixing apparatus, the guide member that accumulates heat therein due to heating performed by the heating unit in the transfer/fixing apparatus is caused to contact with a recording sheet. By conducting heat in the guide member to the recording sheet according to the contact, the recording sheet is advanced in the nip after it has been preheated. In this configuration, by utilizing accumulated heat in the guide member for preheating instead of discharging heat to the atmosphere, the heat loss amount in the transfer/fixing apparatus can be reduced as compared with the apparatus.
In the configuration utilizing the preheating, it is preferable that the transfer member, the heating unit, and the nip forming member in the transfer/fixing apparatus are covered with a casing including a surface-exposing opening that exposes a portion of a surface of the transfer member to cause the portion to face the image carrier, a receiving opening that receives the recording sheet fed from the outside to guide the same to the nip, a discharging opening that discharges the recording sheet discharged from the nip to the outside, and guide units that guide the recording sheet received from the receiving opening toward the nip. It is preferable that a first guide member whose end portion positioned on the side of the receiving opening is cantilevered by a peripheral edge of the receiving opening between the receiving opening and the nip and a second guide member fixed to the peripheral edge of the receiving opening so as to face the first guide member are provided as the guide members, so that the recording sheet advanced in between both of the guide members toward the nip is guided while the receiving opening is closed by causing both of the guide members to contact with each other, and the receiving opening is opened by displacing a free end of the first guide member according to contact with the recording sheet to separate the first guide member from the second guide member. Also, it is preferable that use a member made from flexible material to displace the free end by flexing the free end according to contact thereof with a recording sheet. Also, it is preferable that a transfer roller is used as the transfer member, a nip forming roller is used as the nip forming member, and a contact region between the first guide member and the second guide member is positioned in an upstream region of the nip in surface moving directions of both of the rollers and in a region where circumferential faces of both of the rollers face to each other. Also, it is preferable that a sheet accommodating unit that receives the recording sheet for supplying the recording sheet toward the nip is provided and members whose sizes of faces contacting with the recording sheet in a direction perpendicular to a sheet conveying direction are set to be larger than a size of a recording sheet with the maximum size that can be accommodated in the sheet accommodating unit are used as the first guide member and the second guide member. Also, it is preferable that the first guide member or the second guide member are configured so as to allow displacement thereof by dividing at least a free end thereof into many pieces in a direction perpendicular to the sheet conveying direction. It is preferable that a face of the first guide member contacting with the recording sheet is formed in a curved face extending from the receiving opening toward the nip in an arc shape. It is preferable that a shutter that opens and closes the discharging opening according to drive ON and OFF operations to a drive source is provided. It is preferable that a layout directing the discharging opening vertically in an upward direction is adopted.
A preferable example of the embodiment of the present invention includes a transfer/fixing apparatus that includes a transfer member that transfers a visible image carried on an image carrier to a surface of the transfer member, a heating unit that heats the visible image transferred on the surface of the transfer member, a nip forming member that causes a surface thereof to contact with the surface of the transfer member to form a nip, and a housing including the transfer member, the heating member, and the nip forming member therein, where, while a visible image on the transfer member is fixed on a recording sheet that has been received in the housing from an opening provided in the housing to be nipped in the nip, while the visible image on the transfer member is being transferred on the recording sheet, where a length of the opening in a short side direction thereof is set equal to or less than 5 millimeters. In this aspect, it is further preferable to set the length of the opening in the short side direction equal to or less than 2 millimeters. It is further preferable that a pre-reception guide member that guides a recording sheet after fed out of the sheet supply unit and before received in the opening in the transfer/fixing apparatus toward the opening is provided.
Although the invention has been described with respect to a specific embodiment 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 |
---|---|---|---|
2005-269743 | Sep 2005 | JP | national |
2006-193639 | Jul 2006 | JP | national |
2006-218770 | Aug 2006 | JP | national |