1. Field of the Invention
The present invention relates to a transfer unit transferring an image on an image bearer onto a recoding medium, and an image forming apparatus such as a multifunctional apparatus equipped with at least one of copier, a printer, a facsimile and a plotter having the transfer unit.
2. Discussion of the Background
A transferer or a transfer unit used in an image forming apparatus is conventionally known to have a transfer roller and contact the transfer roller to a drum-shaped or an endless-belt-shaped image bearer upon application of pressure.
Such a transferee applies a bias voltage to the transfer roller or a roller facing the transfer roller, passes a transfer paper between the image bearer and the transfer roller to transfer a toner image formed on the image bearer onto a transfer paper with a pressure and an electrostatic force.
A typical second transfer unit 90 is shown in
The transfer unit 91 has a turning support point 94 for axially supporting the image forming apparatus or a both side unit (not shown) at the bottom. The second transfer unit 90 is pressurized by the both side unit (not shown) through a plate spring 95 when installed in the image forming apparatus so as to hit a protrusion 96 to a fixing unit frame (not shown) of the image forming apparatus such that the second transfer unit 90 is positioned therein.
The second transfer roller 5 contacts the image bearer of the image forming apparatus before the protrusion 96 and the spring 93 is compressed to obtain a predetermined transfer nip pressure.
Japanese published unexamined application No. 2007-148196 discloses an image forming apparatus, in which a second transfer unit is turnably held on the inside face of a both side unit and a L-shaped lock member projected from the inside face of a top edge thereof engages with a bar member of the image forming apparatus such that the second transfer unit and the both side unit are positioned therein, and both collars of the second transfer roller engage with a vertical positioning member of the image forming apparatus such that the second transfer roller is vertically positioned.
The second transfer unit is overall positioned in an image forming apparatus when protrusions 116 formed on inner both ends of the both side unit presses a contact part of 104 of the backside of the second transfer unit (the opposite side face of the second transfer roller).
Since the method of Japanese published unexamined application No. 2007-148196 is a press method with a protrusion as mentioned above, a large force is required to close the both side unit, resulting in deterioration of operability.
Namely, in either of the engagement between the lock member and the bar member or the contact between the contact part and the protrusion, the members serially operates each other, in other words, a positioning force operates in a linear direction and only a turning operation of the both side unit can position the second transfer unit. However, the operation force is inevitably large because of directly receiving a reaction force of the spring pressing the second transfer roller.
A force from the both side unit becomes large in proportion to a pressure of the second transfer roller to the image bearer, and a large force is required to close the both side unit in an image forming apparatus needing a large transfer pressure, resulting in deterioration of operability.
In addition, such a transferer presses the transfer roller to the image bearer even when a toner image is not transferred and the transfer roller is noticeably deformed with pressure if it is formed with a soft material such as sponge rubber and foamed urethane, resulting in defective transfer.
In order to solve this problem, the transfer roller is forcibly separated from the image bearer when a toner image is not transferred or a paper is jammed at a transfer site.
For example, when a predetermined time has passed since the final job was finished or a jamming occurred, a cam equipped in the image forming apparatus is driven to press the transfer roller or the transfer roller holding member such that the transfer roller and the image bearer are separated from each other.
When the both side unit and transfer unit are opened and closed while the transfer roller is separated from the image bearer, a force larger than a closing force while the transfer roller contacts the image bearer is required.
Namely, an extra force is required because the transfer roller and the image bearer are separated from each other by the cam.
Because of these reasons, a need exists for a transfer unit having improved operability and usability, capable of reducing a force for positioning the unit in an image forming apparatus.
Accordingly, an object of the present invention is to provide a transfer unit having improved operability and usability, capable of reducing a force for positioning the unit in an image forming apparatus.
Another object of the present invention is to provide an image forming apparatus using the transfer unit.
These objects and other objects of the present invention, either individually or collectively, have been satisfied by the discovery of a turnable transfer unit, comprising:
a transfer member configured to form a transfer nip while contacting an image bearer installed in an image forming apparatus; and
a pressurizer configured to pressurize the transfer member to the image bearer,
wherein the turnable transfer unit further comprises a turnable lever member, comprising:
an engaging part configured to engage with a positioning part of the image forming apparatus; and
a contact part configured to contact an opening and closing body openable and closable in the image forming apparatus,
wherein the lever turns in conjunction with a closing operation of the opening and closing body to position the transfer unit in the image forming apparatus.
Alternatively, the present invention relates to a turnable transfer unit, comprising:
a transfer member configured to form a transfer nip while contacting an image bearer installed in an image forming apparatus; and
a pressurizer configured to pressurize the transfer member to the image bearer,
wherein the turnable transfer unit further comprises a turnable lever member, comprising:
a turnable second lever comprising an engaging part configured to engage with a positioning part of the image forming apparatus;
a turnable first lever comprising a contact part configured to contact an opening and closing body openable and closable in the image forming apparatus; and
an elastic member formed between the first and the second levers and configured to turn the second lever in the same direction as that of the first lever turned by the engaging part to an engaging direction to the positioning part,
wherein the lever member turns in conjunction with a closing operation of the opening and closing body to position the transfer unit in the image forming apparatus.
These and other objects, features and advantages of the present invention will become apparent upon consideration of the following description of the preferred embodiments of the present invention taken in conjunction with the accompanying drawings.
Various other objects, features and attendant advantages of the present invention will be more fully appreciated as the same becomes better understood from the detailed description when considered in connection with the accompanying drawings in which like reference characters designate like corresponding parts throughout and wherein:
The present invention provides a transfer unit having improved operability and usability, capable of reducing a force for positioning the unit in an image forming apparatus. More particularly, the present invention relates to a turnable transfer unit, comprising:
a transfer member configured to form a transfer nip while contacting an image bearer installed in an image forming apparatus; and
a pressurizer configured to pressurize the transfer member to the image bearer,
wherein the turnable transfer unit further comprises a turnable lever member, comprising:
an engaging part configured to engage with a positioning part of the image forming apparatus; and
a contact part configured to contact an opening and closing body openable and closable in the image forming apparatus,
wherein the lever member turns in conjunction with a closing operation of the opening and closing body to position the transfer unit in the image forming apparatus.
Alternatively, the present invention relates to a turnable transfer unit, comprising:
a transfer member configured to form a transfer nip while contacting an image bearer installed in an image forming apparatus; and
a pressurizer configured to pressurize the transfer member to the image bearer,
wherein the turnable transfer unit further comprises a turnable lever member, comprising:
a turnable second lever comprising an engaging part configured to engage with a positioning part of the image forming apparatus;
a turnable first lever comprising a contact part configured to contact an opening and closing body openable and closable in the image forming apparatus; and
an elastic member formed between the first and the second levers and configured to turn the second lever in the same direction as that of the first lever turned by the engaging part to an engaging direction to the positioning part,
wherein the lever member turns in conjunction with a closing operation of the opening and closing body to position the transfer unit in the image forming apparatus.
Hereinafter, an embodiment of the present invention will be explained, referring to the drawings. First, a first embodiment will be explained, based on
The intermediate transfer belt 11 is supported by a support rollers 16, 17 and 18, and the support roller 16 faces a second transfer roller 5 and the support roller 18 faces an intermediate transfer belt cleaner.
A numeral 9 is a toner bottle container including a toner bottle filled with a yellow toner (Y), a toner bottle filled with a cyan toner (C), a toner bottle filled with a magenta toner (M) and a toner bottle filled with a black toner from left to right in
A transfer paper 2 as a recoding medium is fed from a paper feeding cassette 1 by a paper feed roller 3, and transported to a pair of registration rollers 4 by a pair of transport rollers 19.
A sensor (not shown) detects the transfer paper 2 reaching the pair of registration rollers 4, which transports the transfer paper 2 to a (transfer) nip between the second transfer roller 5 and the intermediate transfer belt 11, determining the timing with a detected signal.
The photoreceptor drums 20Y, 20C, 20M and 20Bk previously charged by the chargers 30Y, 30C, 30M and 30Bk are scanned by an irradiator 8 with a laser beam to form an electrostatic latent image on each of the photoreceptor drums 20Y, 20C, 20M and 20Bk. Each of the electrostatic latent images are developed by each of the image developers 50Y, 50C, 50M and 50Bk to form a yellow, a cyan, a magenta and a black toner image on each surface of the photoreceptor drums 20Y, 20C, 20M and 20Bk, respectively.
Next, a voltage is applied to each of first transfer rollers 12Y, 12C, 12M and 12Bk to sequentially transfer the toner images on the photoreceptor drums 20Y, 20C, 20M and 20Bk onto the intermediate transfer belt 11. Then, the toner images of each color are transferred from upstream to downstream with delayed timing so as to be overlapped on the same position of the intermediate transfer belt 11.
An image overlapping each color formed on the intermediate transfer belt 11 is transported to the second transfer roller 5 and second-transferred onto a transfer paper 2 at a time. The transfer paper 2 on which the image overlapping each color is transferred is transported to a fixer 6, where the image is fixed thereon with heat, and discharged on a tray 21 on the top of the image forming apparatus.
Namely, the image forming apparatus relative to this embodiment is a vertical transport image forming apparatus transporting a transfer paper from paper feeding cassette located below toward a transfer nip located above.
A toner remaining on each of the photoreceptor drums 20Y, 20C, 20M and 20Bk is cleaned by each of the cleaners 40Y, 40C, 40m and 40Bk, and then applied with a DC bias overlapped with an AC bias to the photoreceptor drums 20Y, 20C, 20M and 20Bk by the chargers 30Y, 30C, 30M and 30Bk to discharge and charge them at the same time and they are ready for a following image formation.
A toner remaining on the intermediate transfer belt 11 is cleaned by an intermediate transfer belt cleaner 13, and the intermediate transfer belt 11 is ready for a following image formation.
When the both sides of the transfer paper 2 are printed, it is lead to a both side unit 15, where it is reversed and transported to the pair of registration rollers 4. In
The both side unit 15 includes at least a both side transport route, openable and closable at an image forming apparatus 55. “Openable and closable” includes both meanings of “turnable” and “slidable”.
The both side unit 15 may include a skid for transporting the transfer paper 2 while sandwiching it, a manual tray, a paper feeding skid feeding the transfer paper 2 from the manual tray to the second transferee and a driver such as a motor driving the transport skid and paper feeding skid.
The lever member 66 has a first lever 67 located outside and diagonally extending downward and a second lever 68 located inside. An E ring 69 regulates these levers from being displaced or dropped out in the axial direction. The first lever 67 and the second lever 68 are separate from each other at an interval in the turning direction, and they have a positional angle difference about 90° in this embodiment.
The first lever 67 has a contact part 67b contacting a both side unit 15 as an opening and closing body mentioned later at lower end, and the contact part 67b is fixed on a first lever body 67a with a bolt 70 and a nut (not shown). In this embodiment, the first lever body 67a is formed of a metal and the both side unit 15 and the contact part 67b are formed of synthetic resins to cushion the contact shock therebetween. As a matter of course, the first lever 67 may wholly be formed of a single metal or a resin.
The second lever 68 is formed of a synthetic resin as a single piece as shown in
As shown in
The tensile spring 71 works as a cushion member when the engaging part 68a is engaged in the positioning part of the image forming apparatus 55 mentioned later.
Instead of the tensile spring 71, a link joint (joint member) may joint the both levers to form a joint allowance for cushion. The link joint may be an elastic body such as rubber. Further, instead of the tensile spring 71, a torsion spring may be placed on the axis 65 to bias the second lever 68 toward B and have cushionability.
Between the transfer unit 91 and the first lever 67, a tension spring 72 as a bias means holding the lever member 66 is located such that the engaging part 68a does not reach the engaging position at a turning position (in
When the second transfer unit 60 is positioned to the image forming apparatus 55, an operator does not have to place a hand on the first lever 67 of the lever member 66 and has only to move the both side unit 15 in the direction indicated by an arrow C. Namely, the second transfer unit 60 is positioned in conjunction with closing of the both side unit 15.
The stud 74 may be located at apart besides the intermediate transfer unit 73 of the image forming apparatus 55, but the second transfer unit 60 is more precisely positioned when the stud is located at the intermediate transfer unit 73.
In the closing operation of the both side unit 15, as shown in
When the second transfer roller 5 contacts the intermediate transfer belt 11, the lever member 66 begins to turn in the engaging direction (B direction) as the both side unit closes, receiving a pressure of the spring 93 as a pressurizer, because the tensile spring 72 has a spring force (spring constant) smaller than that of the spring 93.
Finally, as shown in
When the second transfer roller 5 contacts the intermediate transfer belt 11, as shown in
In this embodiment, as shown in
The less set force can make the both side unit 15 (opening and closing body) lighter and smaller. The spring force of the tensile spring 71 is stronger than the reaction force of the spring 93 when the lever member 66 rigidly engages with the stud 74 such that the tensile spring 71 has cushionability.
As shown in
A setting force F can be smaller than that when the pressure position S is equivalent to the operation position 15a because of the principle of leverage due to a difference between a from the turning support of the both side unit 15 to the pressure position S to the contact part 67b and a distance between the turning support and the operation position 15a. In combination with the setting force reduction using the principle of leverage due to the above-mentioned lever ratio, the setting force can be reduced much more than conventional.
The setting force measured by a force gauge when the conventional second transfer unit shown in
When the engagement of the both side unit 15 with the image forming apparatus 55 is released and opened, the spring force of the tensile spring 72 is set such that the lever member 66 turns and the engagement of the engaging part 68a with the stud 74 is released to automatically release the second transfer unit 60.
Since the tensile spring 72 automatically turns the second transfer unit 60 when the both side unit 15 is opened, only a biasing force capable of releasing the engagement with the stud 74 is needed, and which is preferably small. This is because the biasing force of the tensile spring 72 increases the operation force.
As shown in
When the both side unit 15 is opened, as mentioned above, the stud 74 is automatically released from the engaging part 68a and the lever member 66 turns to the initial turning position. In this case, the projection 68c of the second lever 68 follows the track indicated by a two-dot chain line and hits the stopper 75, and the second transfer unit 60 is held open at a predetermined angle to the image forming apparatus 55.
As shown in
When paper jams are resolved, the engagement between the projection 68c and the stopper 75 is released and the second transfer unit 60 is opened at maximum as shown in
The disengagement with the stopper 75 is made by a releaser 76 formed on the back of the transfer unit 91 as shown in
The releaser 76 has a release lever 78, turning axis member 79 holding the release lever 78 and a bracket 80 synchronously turning with the release lever 78. The bracket 80 is partially facing a part of a release racket 81 formed on the first lever 67 in a body. When the release lever 78 is raised, the first lever 67 turns in the direction of engaging with the stud 74. Then, the engagement between the projection 68c and the stopper 75 is released and the lever member 66 turns to the initial position.
As shown in
The image forming apparatus 55 has an eccentric cam 82 pressing a bracket 83 holding the second transfer roller 5 to separate the second transfer roller 5. The shapes of the eccentric cam 82 and the bracket 83 are shown differently from the actual.
While the second transfer roller 5 is separated at a distance w, when an operator opens and closes the second transfer unit 60 for resolving paper jams or carelessly irrespective of resolving paper jams, the lever member 66 begins to turn in the engaging direction sooner for the distance w. Accordingly, the lever member 66 reaches the engaging position before the engaging part 68a of the second lever 68 engages with the stopper 75, and is unengageable.
In this embodiment, as shown in
The guide 84 has an inclined surface 84a expanding outside at an approach side of the projection 68c and a parallel surface 84b holding the projection 68c until it can engage with the stud 74.
Since the projection 68c is forcibly prevented to move up by the guide 84, the engaging part 68a is prevented to move up sooner and the projection 68c can reliably engage with the stud 74. Therefore, while the second transfer roller 5 is separated, even when an operator carelessly opens the both side unit 15, it can prevent the second transfer unit 60 from being defectively set.
In this embodiment, a lever member 85 is a unit body having a compressed spring 86 as an elastic member formed on a contact part 85b, which is a cushion when engaging with the stud 74. In
A numeral 85a is the engaging part 68a and a numeral 85c is the projection 68c in the above-mentioned embodiment.
The lever member 66 in the first embodiment may be a unit body as the lever member 85 is.
In this embodiment, the contact position of the contact part 67b of the lever member 66 to the both side unit 15 is adjustable. A long hole 67a-1 extending in the longitudinal direction of the first lever 67a is formed at the bottom end thereof. After the position of the contact part 67b is adjusted, it is fixed with a bolt 70 and a nut (not shown).
Thus, the contact position of the contact part 67b to the both side unit 15 and the setting force are adjustable, and which is applicable when the contact position with the both side unit 15 needs adjustment.
As a matter of course, the long hole ma be formed at the contact part 67b. The contact part 67b can be screwed in the first lever body 67a and the position can be adjusted with a screw-in quantity.
In each of the above-mentioned embodiments, the second transfer unit 60 is turnably formed on the image forming apparatus 55. Even when the second transfer unit 60 is turnably formed on the both side unit 14, the setting force can be reduced as mentioned above.
In each of the above-mentioned embodiments, the constitution using an intermediate transfer belt as an image bearer is explained. However, the image bearer is not limited to the intermediate transfer belt and all image bearers such as photoreceptor drums, photoreceptor belts and intermediate transfer drums can be used. As for the transfer member, a transfer roller is explained as an example, and all transfer members such as transfer brushes and transfer blades can be used.
The opening and closing body may simply be a cover member besides the both side unit.
Further, as shown in
The distance t is a moving distance applying a predetermined nip pressure between the second transfer roller 5 and the intermediate transfer belt 11 while the spring 93 is pressed. A large setting force has been conventionally needed to directly press a reaction force of the spring 93.
In this embodiment, since a distance R1 from the turnable supporting point 65 to the contact part 67b is different from a distance R2 therefrom to the engaging part 68a (R1/R2 is 2/1), the principle of leverage due to a lever ratio between the first lever 67 and the second lever 68 can reduce the pressure to the contact part 67b more than the conventional method directly receiving the reaction force of the spring 93, and can engage the engaging part 68a with the stud 74 with a force smaller than that of the conventional method. In other words, the both side unit 15 presses the contact part 67b with less set force when engaging.
The less set force can make the both side unit 15 (opening and closing body) lighter and smaller.
The reduction of the setting force will be explained in terms of a force acting on the tensile spring 71.
Supposing the tensile spring 71 is directly pulled without thinking of the presence of the first lever 67 to engage the engaging part 68a with the stud 74, extremely a large force T is needed.
In this embodiment, since the tensile spring 71 is connected with the-first lever 67 at a slant, a force at a connecting (hooking) part P1 to the first lever 67 is T sin θwhich is smaller than the force T.
Since a distance R1 from the turnable supporting point 65 to a contact point S of the contact part 67b is larger than a distance R3 therefrom to a spring connected part P1, a force F for engaging the engaging part 68a with the stud 74 is smaller by the principle of leverage due to a lever ratio.
Therefore, a setting force (an operation force of the both side unit 15) when the second transfer unit 60 is positioned on the image forming apparatus 55 can be reduced.
Furthermore, since a distance L1 from the turnable supporting point 65 to the turnable supporting point 94 of the transfer unit body 94 is larger than a distance L2 from a transfer nip thereto, the setting force is further reduced.
In other words, the first lever 67 and the second lever 68 are connected with each other with the tensile spring 71 in a body, the principle of leverage due to a lever ratio (R1/R2=1/2) can reduce the setting force.
The spring force of the tensile spring 71 is larger than a reaction force of the spring 93 when the lever member 66 engages with the stud 74 so as to rigidly be engaged therewith with a cushion.
Since the cushion with the tensile spring 71 can absorb a shock when the lever member 66 engages with the stud 74, it can prevent the first lever 67 and the second lever 68 from being broken when the lever member 66 is engaged therewith.
In addition, the setting force reduction can form the first lever 67 and the second lever 68 with inexpensive and light materials. Further, the tensile spring 71 as a connecting member combines a cushion member and a separate cushion member is not necessary to form, which is a cost reduction.
In this embodiment, a torsion spring 85 is formed on an axis 65 as an elastic member, and an elastic force is developed against the direction approaching the first lever 67 (second lever 68) to the second lever 68 (first lever 67).
In this embodiment, the second lever 68 does not have a spring locking part 68b for the tensile spring 71.
In this embodiment as well, the principle of leverage due to a lever ratio (a difference of distances from the turnable supporting point) of the both levers can reduce the setting force, and the elasticity of the torsion spring 85 works as impact relaxation.
In this embodiment, the first lever 67 has a shape slightly different from that of the above-mentioned embodiment, and a compressed spring 86 is formed between the first lever body 67a and the under surface of the second lever 68 as an elastic member.
In this embodiment, the second lever 68 does not have a spring locking part 68b for the tensile spring 71.
In this embodiment as well, the principle of leverage due to a lever ratio (a difference of distances from the turnable supporting point) of the both levers can reduce the setting force, and the elasticity of the compressed spring 86 works as impact relaxation. Elastic members such as rubbers may be used instead of the compressed spring 86.
Having generally described this invention, further understanding can be obtained by reference to certain specific examples which are provided herein for the purpose of illustration only and are not intended to be limiting. In the descriptions in the following examples, the numbers represent weight ratios in parts, unless otherwise specified.
This application claims priority and contains subject matter related to Japanese Patent Applications Nos. 2008-176264 and 2008-176267, both filed on Jul. 4, 2008, the entire contents of each of which are hereby incorporated by reference.
Having now fully described the invention, it will be apparent to one of ordinary skill in the art that many changes and modifications can be made thereto without departing from the spirit and scope of the invention as set forth therein.
Number | Date | Country | Kind |
---|---|---|---|
2008-176264 | Jul 2008 | JP | national |
2008-176267 | Jul 2008 | JP | national |