The present invention relates to an image forming apparatus, such as a copying machine, a printer or a facsimile machine, for forming an image by an electrophotographic process or an electrostatic recording process.
In a conventional image forming apparatus toner images carried on an intermediary transfer belt (endless belt) are collectively transferred onto a sheet at a secondary transfer nip (secondary transfer portion) between the intermediary transfer belt and a secondary transfer surface. In order to stably convey the sheet at the secondary transfer portion, in some cases, the secondary transfer roller is connected to and rotated by a motor. In such cases, the intermediary transfer belt is stretched by a plurality of rollers containing a driving roller, so that the intermediary transfer belt receives a driving force for rotational movement from each of the driving roller and the secondary transfer roller.
In such a constitution, when a speed difference between a surface speed of the intermediary transfer belt at a portion where the intermediary transfer belt contacts the driving roller and a surface of the intermediary transfer belt at a portion where the intermediary transfer belt contacts the secondary transfer roller slightly occurs, a tension fluctuation of the intermediary transfer belt is generated. Further, the driving force applied from the secondary transfer roller to the intermediary transfer belt varies depending on the type of the sheet passing through the secondary transfer nip during image formation and an amount of a toner for an image. For this reason, when a speed fluctuation or tension fluctuation of the intermediary transfer belt is generated, toner images transferred from the respective image bearing members onto the intermediary transfer belt are deviated, so that image defect such as color misregistration is generated.
In order to solve this problem, in Japanese Laid-Open Patent Application (JP-A) 2007-164086, the secondary transfer roller contacting the intermediary transfer belt at a position different from the position of the driving roller is provided with a means, such as an encoder, for detecting a rotational speed. Then, on the basis of a detection value of this rotational speed detecting means, rotation control of the driving roller is effected. As a result, the speed difference of the intermediary transfer belt between the secondary transfer portion and the driving roller portion is minimized, so that the tension fluctuation of the intermediary transfer belt can be decreased.
Further, in JP-A 2008-145680, the tension of the intermediary transfer belt is detected by a tension applying member fixedly provided in an image forming apparatus in contact to the intermediary transfer belt. Then, on the basis of its detection result, a speed of the driving roller which controls the speed of the intermediary transfer belt and a speed of a member opposing the driving roller are controlled. As a result, the tension fluctuation of the intermediary transfer belt can be minimized.
However, in the constitution of JP-A 2007-164086, depending on the type of the sheet passing through the secondary transfer nip and the amount of the toner image, the driving force applied from the secondary transfer roller to the intermediary transfer belt with respect to a tangential direction changes in real time. The rotation control of the driving roller cannot follow this change, so that the speed fluctuation of the intermediary transfer belt occurs. As a result, the speed difference of the intermediary transfer belt is generated between the driving roller portion and the secondary transfer portion, thus leaving a problem that the tension of the intermediary transfer belt is fluctuated.
On the other hand, in the constitution of JP-A 2008-145680, by detecting the tension of the intermediary transfer belt, it is possible to follow the change in conveying force applied from the secondary transfer roller to the intermediary transfer belt. However, in order to stabilize the tension, the driving roller and the secondary transfer roller which control the rotational speed of the intermediary transfer belt are provided opposed to each other. For this reason, the intermediary transfer belt receives the driving force at one position with respect to the rotational direction thereof, so that the rotational speed and tension of the intermediary transfer belt are not constant over full circumference of the intermediary transfer belt. Further, the driving roller and the secondary transfer roller which increase and decrease the speed of the intermediary transfer belt are disposed downstream of a primary transfer portion with respect to a movement direction of the intermediary transfer belt. For this reason, a transfer portion is liable to be directly affected by the increase and decrease in speed of the driving roller and the secondary transfer roller during tension control.
A principal object of the present invention is to provide an image forming apparatus capable of suppressing a surface speed fluctuation and tension fluctuation of an endless belt over a full circumference to suppress an occurrence of an image defect.
According to an aspect of the present invention, there is provided an image forming apparatus comprising: an image bearing member for bearing a toner image; a rotatable endless belt; a first driving member for rotationally driving the endless belt in contact to an inner peripheral surface of the endless belt; a second driving member, provided at a position different from a position of the first driving member with respect to a rotational direction of the endless belt, for rotationally driving the endless belt in contact to an outer peripheral surface of the endless belt; a tension detecting unit for detecting a state of tension of the endless belt; and a controller for controlling a rotational speed of the second driving member, wherein a driving force applied from the second driving member to the endless belt is smaller than a driving force applied from the first driving member to the endless belt, and wherein the controller controls, on the basis of a detection result of the tension detecting unit, the rotational speed of the second driving member so that the state of tension of the endless belt is a predetermined state.
According to another aspect of the present invention, there is provided an image forming apparatus comprising: an image bearing member for bearing a toner image; a rotatable endless intermediary transfer belt onto which the toner image is to be primary-transferred from the image bearing member; a first driving source; a driving roller for stretching the intermediary transfer belt and for being rotationally driven by the first driving source; a second driving source; a secondary transfer roller, to be rotationally driven in contact to an outer peripheral surface of the intermediary transfer belt, for secondary-transferring the toner image from the intermediary transfer belt onto a recording material; a tension detecting unit for detecting a state of tension of the endless belt; and a controller for controlling a rotational speed of the secondary transfer roller, wherein the secondary transfer roller is provided at a position different from a position of the driving roller with respect to a rotational direction of the intermediary transfer belt, wherein a driving force applied from the secondary transfer roller to the intermediary transfer belt is smaller than a driving force applied from the driving roller to intermediary transfer belt, and wherein the controller controls, on the basis of a detection result of the tension detecting unit, the rotational speed of the second driving member so that the state of tension of the endless belt is a predetermined state.
These and other objects, features and advantages of the present invention will become more apparent upon a consideration of the following description of the preferred embodiments of the present invention taken in conjunction with the accompanying drawings.
Parts (a) to (c) of
Part (a) of
Parts (a) to (c) of
Parts (a) to (c) of
Parts (a) to (c) of
Parts (a) to (c) of
Hereinbelow, preferred embodiments of the present invention will be exemplarily and specifically described with reference to the drawings. However, dimensions, materials, shapes, relative arrangements and the like of constituent elements described in the following embodiments are appropriately changed depending on constitutions or various conditions of apparatuses to which the present invention is applied. Therefore, the scope of the present invention is not limited thereto unless otherwise specified.
An image forming apparatus according to the First Embodiment of the present invention will be described with reference to the drawings.
On the other hand, a sheet P in a cassette 30 is conveyed to a secondary transfer nip by a feeding roller 31 and a registration roller pair 33, and the four color toner images are secondary-transferred onto the sheet P. The secondary transfer nip T is formed between a secondary transfer roller (second driving member) 20 and the intermediary transfer belt 11 supported by a secondary transfer opposite roller 13. The sheet P on which the toner images are transferred is heated and pressed by a fixing device 40 to fix thereon the toner images and then is discharged onto a discharge tray 42 by a discharging roller pair 41. A transfer residual toner remaining on the intermediary transfer belt 11 after the secondary transfer is removed by an intermediary transfer belt cleaning roller 18.
The intermediary transfer belt 11 is stretched by the intermediary transfer belt driving roller (first driving member) 12, the secondary transfer opposite roller 13, a tension roller 15 and a follower roller 14. Therefore, the intermediary transfer belt driving roller 12 drives the intermediary transfer belt 11 in contact to an inner peripheral surface of the intermediary transfer belt 11, and the secondary transfer roller 20 drives the intermediary transfer belt 11 in contact to an outer peripheral surface of the intermediary transfer belt 11. The intermediary transfer belt driving roller 12 is rotationally driven by an intermediary transfer belt driving motor 28 as a first driving source. The tension roller 15 is urged by a tension spring 16 to apply predetermined tension to the intermediary transfer belt 11. The secondary transfer roller 20 is rotationally driven by a secondary transfer roller driving motor 29 as a second driving source.
(Constitution for Suppressing Tension Fluctuation and Speed Fluctuation of Intermediary Transfer Belt 11)
In the image forming apparatus 100 in this embodiment, the intermediary transfer belt driving roller 12 is provided downstream of the primary transfer portion as a primary transfer nip between the photosensitive drum 2 and the intermediary transfer belt 11 contacted to the primary transfer roller 4, and the secondary transfer roller 20 is provided upstream of the primary transfer portion. The intermediary transfer belt driving roller 12 is larger in driving force, as a force for rotating the intermediary transfer belt 11, than the secondary transfer roller 20. For this reason, the intermediary transfer belt driving roller 12 predominantly controls the rotational speed of the intermediary transfer belt 11.
Here, depending on the presence or absence of the toner or the sheet at the secondary transfer portion as the secondary transfer nip between the secondary transfer roller 20 and the intermediary transfer belt 11 supported by the secondary transfer opposite roller 13, the driving force applied from the secondary transfer roller 20 to the intermediary transfer belt 11 is changed. As a result, there is a possibility of an occurrence of the speed fluctuation of the intermediary transfer belt 11.
Therefore, in this embodiment, a state of tension of the intermediary transfer belt 11 at a position between the primary transfer portion and the secondary transfer portion which are liable to be influenced by the change in the above-described conveying force (driving force) is detected by a tension detecting unit 19 and on the basis of a detection result, the rotational speed of the secondary transfer roller 20 is controlled. As a result, the tension fluctuation and speed fluctuation of the intermediary transfer belt 11 are suppressed.
A constitution for suppressing the tension fluctuation and speed fluctuation of the intermediary transfer belt 11 will be described specifically.
(Tension Detecting Unit)
Parts (a) to (c) of
The tension detecting roller 21 is a metal roller and is contacted to the inner peripheral surface of the intermediary transfer belt 11 at a position between the secondary transfer opposite roller 13 and the photosensitive drum 2Y ((A) in
The tension detecting roller 21 presses down one end portion of the tension detecting member 25 via the connecting member 22 depending on the state of tension of the intermediary transfer belt 11. The tension spring 27 urges the other end of the tension detecting member 25. The tension detecting member 25 is, depending on the balance between the tension state (tension) of the intermediary transfer belt 11 and the urging force of the tension spring 27, rotationally moved about a central rotation center 24 like a see-saw, so that the tension state and the urging force are balanced at a predetermined position.
In this embodiment, a lever ratio between the tension spring 27 and the connecting member 22 was determined in view of the weight of the tension detecting roller 21 or the like so that the tension detecting roller 21 presses the inner peripheral surface (back surface) of the intermediary transfer belt 11 of 240 mm in width with a force of about 5N during a stop of the image forming apparatus 100.
The optical distance measuring sensor 26 is a distance measuring sensor of an infrared type and detects a position of the tension detecting member 25. As shown in (a) of
The light emitting portion 34 emits infrared ray 36 toward the other end portion (objected to be subjected to distance measurement) of the tension detecting member 25. Reflected light diffused and reflected by the object to be subjected to distance measurement is focused by a focusing means 35 for light receiving provided in front of a light receiving surface 32a of the PSD 32, thus being guided to the light receiving surface 32a. Based on a position of a center of distribution of the infrared ray which reaches the light receiving surface 32a, a distance to the measurement object is calculated by the triangulation. In this method, the position of the distribution center of the infrared ray which reaches the light receiving surface 32a is converted into the distance and therefore even when a reflectance is changed depending on a surface state of the measurement object, the change does not influence a distance data.
Further, the position detected by the light receiving portion 32 is converted into the distance by an processing IC and then the converted distance is outputted as a voltage value. Part (b) of
Here, with reference to (a) to (c) of
Part (b) of
Part (c) of
Thus, from the distance measured by the optical distance measuring sensor 26, it becomes possible to detect the tension of the intermediary transfer belt 11. Incidentally, in this embodiment, the part linked to the tension detecting roller 21 is provided and the position thereof is detected by the optical distance measuring sensor 26 but the position of the tension detecting roller 21 may also be directly detected by the optical distance measuring sensor 26.
(Controller for Intermediary Transfer Belt Driving Motor 28 and Secondary Transfer Roller Driving Motor 29)
RAM 72 in a CPU 42 stores a target tension AD value as a control target. A secondary transfer driving roller motor rotation number determining portion 75 determines the rotation number of the motor 29 by using the target tension AD value stored in the RAM 74 and the tension AD value of the intermediary transfer belt 11 sent to the CPU 42. Information on the determined motor rotation number is sent to a secondary transfer roller driving motor rotation number setting portion 47 in a secondary transfer roller driving motor controller 76 and then on the basis of the set rotation number, the controller 76 controls the secondary transfer roller driving motor 29 to rotationally drive the secondary transfer roller 20.
The controller 49 and the secondary transfer roller motor controller 76 constitute the control portion for controlling, on the basis of a detection result of the tension detecting unit 19, the speed of the secondary transfer roller 20 so that the speed fluctuation of the intermediary transfer belt 11 is suppressed.
In this embodiment, the control is effected by using PI control of the motor rotation number so that the tension AD value during an operation converges to the target tension AD value. A proportional gain for P (proportional) control was determined in a range in which the tension AD value does not cause overshooting and bunting with respect to the target tension AD value. This is because when the overshooting and hunting are generated, the tension fluctuation is generated and thus color misregistration or the like is caused. Further, with respect to deviation (offset) from the target AD value such that the tension AD value is left without reaching the target tension AD value only by the proportional control, an integral control parameter was determined so as to remove the deviation by I (integral) control. By adding the integral control, an output change is continued so long as the offset occurs and therefore the offset is gradually attenuated, so that the tension AD value converges to the target tension AD value.
On the other hand, the intermediary transfer belt driving motor 28 which dominantly controls the speed of the intermediary transfer belt 11 is constituted by a DC brush-less motor and is drive-controlled by the intermediary transfer belt driving motor controller 48. The intermediary transfer belt driving motor controller 48 controls the intermediary transfer belt driving motor 28 by receiving a rotational state signal from the driving motor 28 so that the rotation number suitable for the image formation is provided.
(Color Misregistration and Transfer Deviation)
The color misregistration is known and will be omitted from detailed description. The color misregistration is an image defect generated by misregistration of the toner images of Y (yellow), M (magenta), C (cyan) and K (black). The color misregistration remedied by the present invention is caused by the speed fluctuation of the intermediary transfer belt 11 with respect to the rotational direction (movement direction) of the intermediary transfer belt 11.
For this reason, an effect of the present invention was evaluated in terms of the color misregistration with respect to the movement direction (sub-scan direction) of the intermediary transfer belt 11. In general, the color misregistration is easily recognizable when a size thereof is 150 μm or more and therefore it is desirable that the color misregistration is 100 μm or less in size. It is further desirable that the color misregistration is 50 μm or less in size. As a result, blur of a character due to the color misregistration and color shift of a process color (mixed color of two or more colors) are not conspicuous.
The transfer deviation remedied by the present invention is caused by instantaneous speed fluctuation or tension fluctuation of the intermediary transfer belt 11. An occurrence mechanism thereof will be described below. When a speed difference between the secondary transfer roller 20 and the intermediary transfer belt 11 is generated even in a slight degree during post-rotation or sheet interval (state between the current sheet and a subsequent sheet) in which the sheet and the toner are not present in the secondary transfer nip, the intermediary transfer belt 11 receives a large driving force from the secondary transfer roller 20. As a result, on the intermediary transfer belt 11, a tension-relieved state and a tension(-applied) state can be generated. This is conspicuous in the case where a friction coefficience between the secondary transfer roller 20 and the intermediary transfer belt 11 is large.
On the other hand, when the sheet and the toner are present in the secondary transfer nip (portion), a sliding (lubricating) effect is generated in the secondary transfer nip, so that the tangential force applied from the secondary transfer roller 20 to the intermediary transfer belt 11 becomes small. For this reason, at the instant when the sheet and the toner enter the secondary transfer nip T, the instantaneous tension fluctuation or speed fluctuation is generated on the intermediary transfer belt 11. This tension fluctuation or speed fluctuation is transmitted to the primary transfer portion to cause deviation or slippage, so that the image is blurred. This phenomenon is referred to as the transfer deviation.
(Suppressing Effect of Tension Fluctuation of Intermediary Transfer Belt 11)
In
In
The line (1) in
Line (2) in
As described above, in the case where the secondary transfer roller 20 is rotationally driven, when the speed difference is generated between the conveyance speed of the intermediary transfer belt 11 by the motor 29 and the conveyance speed of the intermediary transfer belt 11 by the motor 28, the tension fluctuation is generated depending on the image forming process. When the tension fluctuation is generated, the tension fluctuation is transmitted to the primary transfer portion, so that a possibility that the image defect such as the color misregistration or an image deviation is generated is increased.
Line (3) in
As shown by the line (3) in
The print job of 2 pages in 1-page intermittent manner was executed 10 times, thus forming the image on 20 sheets in total in each of the conventional image forming apparatus and the image forming apparatus in this embodiment. With respect to occurrence probability of the transfer deviation and the color misregistration with respect to the sub-scan direction, comparison between the conventional image forming apparatus and the image forming apparatus in this embodiment was made. In the case where the conventional image forming apparatus was used (in the cases of the lines (1) and (2) in
(Suppressing Effect of Speed Fluctuation of Intermediary Transfer Belt 11)
Parts (a) to (c) of
Part (a) of
Part (b) of
Part (c) of
As is understood from (a) to (c) of
Parts (a) to (c) of
In this embodiment, in the case where the tension-relieved state of the intermediary transfer belt 11 at the portion (A) is detected, in order to eliminate the tension-relived state, the speed of the secondary transfer roller 20 is lowered. On the other hand, during the period, the secondary transfer opposite roller 13 is rotated in a steady state so that the speed of the intermediary transfer belt 11 is made constant. Therefore, as is understood from (a) to (c) of
As described above, the driving source (for the intermediary transfer belt driving roller 12) which is provided downstream of the primary transfer portion and which has a large driving force dominantly controls the speed of the intermediary transfer belt 11 and ensures speed stability which is not affected by disturbance or the like. Further, the driving source (for the secondary transfer roller 20) which is provided upstream of the primary transfer portion and which has a small driving force is subjected to the rotational speed control on the basis of the tension detection result.
As a result, in the case where the rotational speed of the secondary transfer roller 20 is controlled, compared with the case where the rotational speed of the driving roller 12 is controlled, the speed fluctuation of the intermediary transfer belt 11 can be suppressed. For this reason, the tension fluctuation of the intermediary transfer belt 11 can be suppressed while suppressing the speed fluctuation of the intermediary transfer belt 11, so that the color misregistration and the transfer deviation can be suppressed.
Further, in the case where the driving roller 12 and the secondary transfer roller 20 are disposed at the same position or close positions, it is difficult to control the rotational speed and tension of the intermediary transfer belt 11 at a position remote from the driving roller 21 and the secondary transfer roller 20. However, in this embodiment, the driving roller 12 and the secondary transfer roller 20 are contacted to the intermediary transfer belt 11 at different positions (which are disposed upstream and downstream of the primary transfer portion and are remote from each other). As a result, the rotational speed and tension of the intermediary transfer belt 11 can be controlled at substantially the same level over the full circumference of the intermediary transfer belt 11.
(Driving Fore)
In this embodiment, tension information obtained by the tension detecting unit 19 is fed back to the secondary transfer roller 20 having the small driving force, not the intermediary transfer belt driving roller 12 having the large driving force.
The intermediary transfer belt driving roller 12 is disposed inside the intermediary transfer belt 11 and is disposed so that the intermediary transfer belt 11 is wound about the driving roller 12. Thus, the roller 21 has a portion where the intermediary transfer belt 11 is wounded about the roller 12 and therefore has the large driving force. A driving force F1 of the roller 12 can be represented by an equation (1) shown below on the basis of the Euler's belt theory.
When a static friction coefficient between the surface of the roller 12 and the back (inner) surface of the intermediary transfer belt 11 is μ1, a winding angle of the intermediary transfer belt 11 is θ and a tension of the intermediary transfer belt 11 at a belt surface is T, the driving force F1 is obtained by the following equation (1):
F1=T·eμ
A driving force F2 of the secondary transfer roller 20 disposed outside the intermediary transfer belt 11 is obtained by an equation (2) shown below when a total pressure of the secondary transfer nip is N and a static friction efficient between the surface of the secondary transfer roller 20 and the surface of the intermediary transfer belt 11 is μ2.
F2=μ2·N (2)
In this embodiment, μ1=0.6, T−30 (N), 0=2.27 (rad)=130 (deg), μ2=0.5 and T=20 (N) and therefore F1=117 (N) and F2=10 (N) are obtained. As a result, F1>F2 is satisfied.
(Secondary Transfer Roller 20)
The secondary transfer roller 20 was prepared by coating a 6 mm-thick electroconductive foam rubber layer on a core metal of SUS to have a hardness of 30 degrees (Asker-C hardness under load of 4.9 N (500 gf)), an outer diameter of 18 mm, and an electric resistance value of 1×107Ω. The secondary transfer roller 20 is urged in one direction by an unshown spring to form the secondary transfer nip T and is rotationally driven by the secondary transfer driving motor 29.
The polyimide resin tube 55 as the outermost surface layer was 50 μm in thickness, about 0.3 μm in average surface roughness Tz, 18 mm in outer diameter and 65 degrees (Asker-C hardness under load of 9.8 N (1000 gf)). As a material for the surface layer, polyimide was used but other resin materials such as polycarbonate, polyvinylidene fluoride (PVDF), polyethylene, polypropylene, polyamide, polyalylate, polyethylene terephthalate, polyether sulfone and thermoplastic polyimide may also be used. Further, as the surface layer, it is possible to provide a curable layer of acrylic resin or the like and an elastic layer of a solid rubber or the like.
The secondary transfer roller 20 is the roller coated with the polyimide tube 55 and generates a high frictional force between itself and the intermediary transfer belt 11 formed of a similar resin material. This is because these surface resin materials have a high lubricating property and therefore a true contact area in the secondary transfer nip is large to increase a depositing force due to the Van der Waals force or the like.
In such a case, the tangential force fluctuation in the secondary transfer nip T is also increased, so that the tension fluctuation of the intermediary transfer belt 11 is also increased. Further, also in the case where the surface layer of the secondary transfer roller 20 is the coating layer and in the case where the solid rubber roller is used, similarly, the tangential force in the secondary transfer nip is also increased.
Incidentally, as the intermediary transfer belt 11, an endless resin belt which was adjusted to have a volume resistivity of about 1010 ohm·cm and was 100 μm in thickness was used. As a material for the belt, in this embodiment, PVDF was used but other resin materials such as polyimide polycarbonate, polyvinylidene fluoride (PVDF), polyethylene, polypropylene, polyamide, polyalylate, polyethylene terephthalate, polyether sulfone and thermoplastic polyimide may also be used. Further, on the surface of these layers, it is possible to provide a curable layer of acrylic resin or the like. Further, the intermediary transfer belt driving roller 12 was prepared by coating a 0.5 mm-thick EPDM rubber on a hollow aluminum pipe of 24 mm in outer diameter to have an electric resistance of 105Ω or less.
Incidentally, the present invention is not limited to the image forming apparatus using the intermediary transfer belt 11 but may also be, as shown in
The sheet conveying belt driving roller 64 has a conveying force larger than the attraction roller 72. The attraction roller 72 electrostatically attracts the conveyed sheet to a sheet conveying belt 71. The sheet conveying belt driving roller 64 is provided downstream of the primary transfer portion and the attraction roller 72 is provided upstream of the primary transfer portion. The rollers 64 and 72 are controlled similarly as in the above-described control.
An image forming apparatus according to the Second Embodiment of the present invention will be described with reference to
As shown in (a) to (c) of
The tension roller 15 is urged against the intermediary transfer belt 11 at a position downstream of the driving roller 12 with respect to the intermediary transfer belt movement direction to apply predetermined tension to the intermediary transfer belt 11 from the inside of the intermediary transfer belt 11. The optical distance measuring sensor 26 is provided outside the intermediary transfer belt 11 and detects the position of the tension roller 15 via the intermediary transfer belt 11.
In this embodiment, the tension roller 15 was 12 mm in outer diameter and was disposed so that the winding angle of the intermediary transfer belt 11 about the tension roller 15 was 70 degrees. As the tension spring 16, a spring capable of applying the tension of 20 N to the intermediary transfer belt 11 of 240 mm in width was selected. Further, the tension roller 15 was constituted in such a manner that a light-weight hollow pipe of aluminum was used to minimize the force of inertia and a shaft is freely movable so that the tension roller 15 can sensitively follow the tension fluctuation of the intermediary transfer belt 11. Further, as the tension spring 16 used, a spring having a small spring constant is selected to the possible extent, so that the tension spring 16 can urge the tension roller 15 with a certain force without changing a spring force when a spring length is fluctuationed.
Part (a) of
Part (c) of
The position of the tension roller 15 is detected by the optical distance measuring sensor 26, so that the tension of the intermediary transfer belt q11 in the neighborhood of the tension roller 15 (at the portion (A) in
As a result, also in this embodiment, similarly as in the First Embodiment, the speed fluctuation of the intermediary transfer belt with the tension correction an be suppressed over the entire image formation simultaneously with the suppression of the tension fluctuation of the intermediary transfer belt, so that it is possible to suppress the color misregistration and the transfer deviation.
An image forming apparatus according to the Third Embodiment of the present invention will be described with reference to
As shown in (a) to (c) of
The tension detecting roller 61 is provided in contact to the intermediary transfer belt 11 at a position ((A) in
The connecting member 43 connects the tension detecting rollers 61 and 62. The tension detecting rollers 61 and 62 and the connecting member 43 are configured so that their positions are determined depending on the balance with the tension of the intermediary transfer belt 11.
The detecting member 45 is connected to the connecting member 43 at one end portion thereof, so that the connecting member 43 capable of being moved vertically by the tension of the intermediary transfer belt 11 is rotationally moved about a rotation center 44 depending on a degree of movement thereof. The infrared distance measuring sensor 26 detects the other end of the tension detecting member 45.
The stretching roller 46 is fixedly provided at a position where it stretches the intermediary transfer belt 11, so that the tension of the intermediary transfer belt 11 is applied by urging the intermediary transfer belt 11 with the tension detecting rollers 61 and 62. In this embodiment, the tension detecting rollers 61 and 62 enter, during a rest state of the image forming apparatus, the intermediary transfer belt 11 at the portions (A) and (C) in
Part (a) of
Part (c) of
As described above, by detecting the position of the other end portion of the tension detecting member 45 by the optical distance measuring sensor 26, so that the tension of the intermediary transfer belt, the tension (state) of the intermediary transfer belt 11 at the position ((A) in
As a result, also in this embodiment, similarly as in the First Embodiment, the speed fluctuation of the intermediary transfer belt with the tension correction an be suppressed over the entire image formation simultaneously with the suppression of the tension fluctuation of the intermediary transfer belt, so that it is possible to suppress the color misregistration and the transfer deviation.
Further, the tension detecting unit 59 in this embodiment performs the tension detection at the position of the tension detecting member 45 determined by the balance of tension at each of the two positions of the intermediary transfer belt 11. That is, the tension detection is performed only by using the tension of the intermediary transfer belt 11 without via the spring or the like and therefore it becomes possible to perform high-responsive detection with high accuracy.
While the invention has been described with reference to the structures disclosed herein, it is not confined to the details set forth and this application is intended to cover such modifications or changes as may come within the purpose of the improvements or the scope of the following claims.
This application claims priority from Japanese Patent Application No. 152847/2011 filed Jul. 11, 2011, which is hereby incorporated by reference.
Number | Date | Country | Kind |
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2011-152847 | Jul 2011 | JP | national |
Number | Name | Date | Kind |
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7155144 | Atwood et al. | Dec 2006 | B2 |
7593664 | Okabe | Sep 2009 | B2 |
20070059055 | Iwata | Mar 2007 | A1 |
20070147894 | Yokota | Jun 2007 | A1 |
20110194879 | Nomura et al. | Aug 2011 | A1 |
20120207494 | Tomura et al. | Aug 2012 | A1 |
20130016983 | Kawakami | Jan 2013 | A1 |
Number | Date | Country |
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2007-164086 | Jun 2007 | JP |
2008-145680 | Jun 2008 | JP |
2012123044 | Jun 2012 | JP |
Number | Date | Country | |
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20130016984 A1 | Jan 2013 | US |