This application is based on and claims priority under 35 USC 119 from Japanese Patent Application No. 2011-069697 filed Mar. 28, 2011.
(i) Technical Field
The present invention relates to a paper transport device and an image forming apparatus.
(ii) Related Art
In a paper transport device that is mounted on an image forming apparatus to transport paper within the image forming apparatus, the following detecting sections are known as a detecting section that detects the passage of paper through a transport path.
According to an aspect of the invention, there is provided a paper transport device including a transport section that transports paper to a reversal position in a first direction on a first transport path, and reverses a transport direction to a second direction that is a direction opposite to the first direction at the reversal position, to transport the paper onto a second transport path that branches from the first transport path; and a detecting section that detects that the paper is transported in the first direction, and has arrived at the reversal position, wherein the detecting section includes a first member that is arranged closer to the reversal position side than a branch point on the first transport path branched to the second transport path, and changes posture thereof among a first posture free of the contact with paper, a second posture where the first member comes into contact with the paper transported in the first direction and has rotated in the first direction from the first posture, and a third posture where the first member comes into contact with the paper transported in the second direction and has rotated in the second direction from the first posture, after the paper has passed in the first direction; a second member that changes posture thereof between a fourth posture and a fifth posture by rotation; a detector that detects whether the second member is in the fourth posture or in the fifth posture; and a joint member that couples the first member and the second member together, allows the second member to be in the fourth posture when the first member is in the first posture, rotates the second member to the fifth posture when a movement in which the first member rotates toward the second posture from the first posture is transmitted to the second member and the first member has rotated to the second posture, and does not transmit a movement in which the first member rotates toward the third posture from the first posture, to the second member, and keeps the second member in the fourth posture.
Exemplary embodiments of the present invention will be described in detail based on the following figures, wherein:
An exemplary embodiment of the invention will be described below.
An image forming apparatus as one exemplary embodiment of the invention and a paper transport device as one exemplary embodiment of the invention are incorporated into the copying machine shown in
The copying machine 1 has a document reader 10 and an image forming apparatus 20. The document reader 10 is installed at a distance from the image forming apparatus 20 on the image forming apparatus 20 by a frame 30.
The document reader 10 includes a document paper tray 11 on which document sheets S are placed in a superimposed state. The document sheets S placed on the document paper tray 11 are fed out one by one, and are transported on a transport path (not shown) inside the document reader 10. During the transport, characters and images that are recorded on the transported document sheet are read by a document reading optical system 13 placed under a document reading platen 12 made of transparent glass. A document sheet S from which characters and images are read is further transported on the transport path, and is ejected onto a document ejection shelf 14.
Additionally, the document reader 10 has a hinge that extends in the depth direction in the drawing, on the right of the drawing, and the document paper tray 11 and the document ejection shelf 14 are integrally lifted with the hinge as a center of rotation. The document reading platen 12 spreads under the raised document paper tray 11 and document ejection shelf 14.
In the document reader 10, when only one document sheet is placed downward on the document reading platen 12 instead of placing document sheets on the document paper tray 11, the document reading optical system 13 moves from the deep side in the drawing to the near side, and reads characters and images from the document sheet on the document reading platen 12.
Additionally, the document reader 10 is equipped with an operation panel 15 on the left in the drawing. As a user operates the operation panel 15, various setting contents, such as output form of images such as double-sided printing or single-sided printing, or the number of copies, may be input. A setting signal indicating the setting contents input by the operation panel 15 is input to the image forming apparatus 20 from the document reader 10.
Additionally, an image signal acquired as characters and images of a document sheet are read by the document reading optical system 13 is input to the image forming apparatus 20 from the document reader 10.
The image forming apparatus 20 forms an image on the basis of the input image signal as follows.
The image forming apparatus 20 is equipped with a control section 21 that controls the movement of respective constituent elements in the image forming apparatus 20. The setting signal and image signal that are input from the document reader 10 are input to the control section 21 of the image forming apparatus 20. In the image forming apparatus 20, the formation of an image on the basis of the input setting signal and image signal is performed under the control of the control section 21.
Two paper trays 31 are accommodated in a lower part of the image forming apparatus 20. Paper P with different sizes for every paper tray 31 is stored in a stacked state in the paper trays 31. Each paper tray 31 is drawably configured for supply of paper P.
Paper P is fed out by a pickup roller 32 from a paper tray of the two paper trays 31 that stores the paper P of a size matched to the size of a document sheet, or a size set in the setting signal. The fed-out paper P is separated one by one by a separation roller 33, one sheet of the separated paper P is transported upward, and the leading edge of the paper P arrives at a standby roller 34. The standby roller 34 serves to adjust the timing of the subsequent transport, and feed out the paper P, and the paper P that has arrived at the standby roller 34 is further transported after the subsequent transport timing is adjusted by the standby roller 34.
In the mage forming apparatus 20, a photoreceptor 22 that rotates in a direction indicated by arrow A is provided above the standby roller 34. A charger 23, an exposure device 24, a developing device 25, a transfer device 26, and a cleaner 27 are arranged around the photoreceptor 22.
The photoreceptor 22 has a cylindrical shape, holds charges by charging, and discharges the charges by exposure, to form an electrostatic latent image on the surface thereof.
The charger 23 charges the surface of the photoreceptor 22 with a certain charging potential.
Additionally, the image signal acquired by the document reader 10 as mentioned above is input to the exposure device 24 from the control section 21. The exposure light modulated according to the image signal is output from the exposure device 24. The photoreceptor 22 receives exposure caused by the exposure light, and an electrostatic latent image is formed on the surface of the photoreceptor 22.
Moreover, the photoreceptor 22 is exposed by the exposure light and has an electrostatic latent image formed on the surface thereof and then developed by the developing device 25. The developing device 25 includes a toner storage part 25a, a toner supply passage 25b, and a developing roller 25c. In the developing device 25, a toner stored in the toner storage part 25a is fed to the vicinity of the developing roller 25c through the toner supply passage 25b. Then, development is performed by the developing roller 25c as the toner is supplied to the photoreceptor 22, and a toner image is formed on the surface of the photoreceptor 22.
Here, the standby roller 34 feeds out paper P such that the toner image on the photoreceptor 22 arrives at a position that faces the transfer device 26 at the timing that the toner image arrives at the position. Then, the toner image on the photoreceptor 22 receives an action of the transfer device 26, and is transferred to the fed-out paper P.
The toner that remains on the photoreceptor 22 after the transfer of the toner image is removed from the photoreceptor 22 by the cleaner 27.
The paper P that has received the transfer of the toner image further advances in the direction of arrow B, and an image consisting of a fixed toner image is formed on the paper P under the heating and pressurization of a fixing device 100.
A combination of the photoreceptor 22, the charger 23, the exposure device 24, the developing device 25, the transfer device 26, and the fixing device 100 is equivalent to an example of the image forming section in the exemplary embodiments of the invention.
The paper P that has passed through the fixing device 100 advances in the direction of arrow C toward an ejector 200, is further fed in the direction of arrow D and ejected onto a paper ejection shelf 28 by the ejector 200.
Here, the image forming apparatus 20 is an apparatus that may form images on both sides of paper P. When images are formed on both sides of paper P, the paper P on which an image is formed only on a first side of the paper P as described above is transported to a reversal position where the trailing edge of the paper has entered the ejector 200 in the direction of arrow C and the direction of arrow D by the ejector 200. Thereafter, the ejector 200 reverses the transport direction of the paper in the direction of arrow E opposite to the direction of arrow D at the reversal position, and the paper P is pulled in the direction of arrow E. The pulled-in paper P advances in the direction of arrow F this time, is further transported in the direction of arrows G and H by a transport roller 35, and arrives at the standby roller 34 again. When the standby roller 34 is returned to, the front and back of the paper P are reversed. Then, the standby roller 34 feeds out the paper P, with a second side opposite to the first side on which an image is already formed directed to the photoreceptor 22 side. Thereafter, an image is formed on the second side similarly to the formation of an image on the first side. The paper P on both sides of which images are formed is now ejected onto the paper ejection shelf 28.
Additionally, in the image forming apparatus 20, a rear panel 29 that covers the fixing device 100 and the ejector 200 is adapted so as to be rotated and opened in the direction of arrow I about a fulcrum 29a. In a case where paper P is jammed between the fixing device 100 and the ejector 200, the rear panel 29 is opened by a user. Then, the user inserts his/her hand into an opening, which has appeared by opening the rear panel 29, from the underside of the document reader 10, and removes the jammed paper P.
The fixing device 100 has a heating roller 101 and a pressure roller 102. The heating roller 101 is a tubular roller that has a heat source 101a therein, and the peripheral surface of the pressure roller 102 that is similarly tubular is pressed against the peripheral surface of the heating roller 101. The paper that has advanced in the direction of arrow B and arrived at the fixing device 100 is guided to a contact portion between the pressure roller 102 and the heating roller 101 by a paper guide 103. The paper is nipped between the heating roller 101 and the pressure roller 102 at the contact portion.
The heating roller 101 and the pressure roller 102 rotate in the direction of arrow J while being brought into contact with each other. For this reason, the paper guided to the contact portion is nipped between the heating roller 101 and the pressure roller 102 at the contact portion, and advances toward the ejector 200. In that case, an image consisting of a fixed toner image is formed on the paper under the heating by the heating roller 101 and the pressurization by the pressure roller 102.
The ejector 200 has a lower frame 201 that plays the role of a lower guide in a first transport path 20a that passes through the fixing device 100 and passes through the inside of the ejector 200, and an upper frame 202 that plays the role of an upper guide.
A paper ejection roller 203 that feeds the paper, which has come out of the fixing device 100 in the direction of arrow C, sequentially in the direction of arrow C on the first transport path 20a, and further feeds the paper in the direction of arrow D, is supported by the lower frame 201.
When the output form set in the setting signal input to the control section 21 from the document reader 10 is single-sided printing, paper is transported in the direction of arrow D on the first transport path 20a and ejected onto the paper ejection shelf 28 as it is by the paper ejection roller 203.
On the other hand, when the output form set in the setting signal is double-sided printing, paper on which an image is formed only on the first side is transported as follows by the paper ejection roller 203. In this case, the paper is first transported in the direction of arrows C and D on the first transport path 20a until the trailing edge of the paper arrives at the reversal position where the paper has entered the ejector 200. The ejector 200 has a detecting section 300 for detecting that paper has arrived at the reversal position. The detecting section 300 will be described below in detail.
When the detecting section 300 detects that paper has arrived at the reversal position, the rotation of the paper ejection roller 203 is reversed according to an instruction of the control section 21, whereby the transport direction of the paper is reversed in the direction of arrow E opposite to the direction of arrow D. Then, the paper is transported by the paper ejection roller 203 onto a second transport path 20c that branches from the first transport path 20a at a branch point 20b between the fixing device 100 and the ejector 200.
The transport of paper onto the second transport path 20c will be described below with reference to both
The fixing device 100 has a frame 100a that rotatably supports the heating roller 101 and the pressure roller 102. In the fixing device 100, a cover 104 that covers the contact portion between the heating roller 101 and the pressure roller 102 is attached so as to be openable or closable around the fulcrum 104a in the frame 100a. The cover 104 is closed in a state where the portion of the cover that is directed to the contact portion strikes an overhang portion 100a_1 that overhangs the pressure roller 102 in the frame 100a of the fixing device 100.
Additionally, the frame 100a of the fixing device 100 has a fixing-device-side guide rib 100a_2 that guides paper to the ejector 200 on the first transport path 20a. As shown in
The paper that has come out of the fixing device 100 pushes up the tip of the cover 104 and advances in the direction of arrow C on the first transport path 20a. On the other hand, the advance of the paper, which is transported in the direction of arrow E by the reversal of the paper ejection roller 203, on the first transport path 20a, is obstructed by the cover 104 in the place where the paper arrives at the branch point 20b. As a result, the paper is transported in the direction of arrow F on the second transport path 20c that branches from the first transport path 20a at the branch point 20b, and passes through the top face side of the cover 104. The second transport path 20c is a path that arrives at the standby roller 34 (refer to
The ejector 200 is equivalent to one exemplary embodiment of the paper transport device in the exemplary embodiments of the invention. The paper ejection roller 203 is equivalent to one exemplary embodiment of the paper transport device in the exemplary embodiments of the invention.
Here, in the image forming apparatus 20, in a case where paper P is jammed between the fixing device 100 and the ejector 200, as described with reference to
As shown in
When a user operates the operating lever 105 to open the cover 104, a transport path from the contact portion between the heating roller 101 and the pressure roller 102 to the ejector 200 in the first transport path 20a shown in
In the ejector 200, the paper that has come out of the fixing device 100 in the direction of arrow C advances into a transport path (a portion of the first transport path 20a shown in
The paper that has advanced into the internal ejector path 20a_1 is transported in the direction of arrow D by the paper ejection roller 203. Additionally, in the case of double-sided printing, the transport direction of paper by the paper ejection roller 203 is reversed in the direction of arrow E after the paper is transported in the direction of arrow D until the trailing edge of the paper enters the internal ejector path 20a_1 and arrives at the reversal position. Then, the paper after the reversal is fed out to the second transport path 20c in the direction of arrow F from the ejector 200.
The ejector 200 has the detecting section 300 for detecting that paper has arrived at the reversal position. The detecting section 300 is equivalent to an example of the detecting section in the exemplary embodiments of the invention.
The detecting section 300 has a first member 310, a second member 320, a detector 330, and a joint member 340.
The first member 310 is pushed and moved by the paper transported in the direction of arrow D or the direction of arrow E on the internal ejector path 20a_1, and changes posture thereof among three postures that will be described below. The first member 310 has a rotating shaft 311 that extends in the paper width direction. The rotating shaft 311 is rotatably inserted into a through hole 202b that is provided in the upper frame 202 and extends in the paper width direction from the center of the upper frame 202 to an oblique upper right end in the drawing.
The second member 320 changes posture thereof between two postures that will be described below.
The detector 330 detects whether the second member 320 takes any posture of the two postures. The detector 330 is attached to the lower frame 201.
The joint member 340 couples the first member 310 and the second member 320 together.
The first member 310 has the rotating shaft 311 and the detecting claw 312.
The detecting claw 312 is a member that is formed integrally with the rotating shaft 311 at one end of the rotating shaft 311 that extends in the paper width direction and whose tip is extended from the rotating shaft 311. As described above, the rotating shaft 311 is rotatably inserted into the through hole 202b provided in the upper frame 202 of the ejector 200. The detecting claw 312 that is extended from the rotating shaft 311 is arranged closer to the reversal position than the branch point 20b on the internal ejector path 20a_1.
Here, in the present exemplary embodiment, paper P with mutually different sizes from the two paper trays 31 shown in
Then, the detecting claw 312 is arranged at the longitudinal center of the ejector 200 shown in
Across-section, which passes through the detecting claw 312 so as to cross the rotating shaft 311, in the first member 310 of the detecting section 300 is shown in
Here, a torsion spring 350 for a detecting claw that will be described below is attached to the first member 310.
The torsion spring 350 for a detecting claw is a spring that generates an urging force between the detecting claw 312 and the upper frame 202, and is attached to the rotating shaft 311 so as to be wound around the portion of the rotating shaft 311 in the vicinity of the detecting claw 312. One end 351 of the torsion spring 350 for a detecting claw is fixed to a projection 312a provided at the detecting claw 312. Additionally, the other end 352 of the torsion spring 350 for a detecting claw is fixed to a projection 202c shown in
The first member 310 takes a first posture where the tip of the first member is extended to the internal ejector path 20a_1, when paper has not passed through the internal ejector path 20a_1 shown in
As shown in
The second member 320 is a plate that crosses the rotating shaft 311 and whose tip is extended in the direction of separating from the rotating shaft 311. Additionally, in the present exemplary embodiment, the second member 320 has a larger thickness on the tip side than the thickness of a root portion on the rotating shaft 311 side.
The joint member 340 couples the rotating shaft 311 and the second member 320 together, and has a first joint portion 341, a second joint portion 342, and a torsion spring 343 for a joint.
The first joint portion 341 is formed integrally with the rotating shaft 311 at the other end of the rotating shaft 311. Additionally, the second joint portion 342 is formed integrally with the second member 320.
The torsion spring 343 for a joint is attached to the first joint portion 341 and the second joint portion 342 so as to be wound around the both the first joint portion 341 and the second joint portion 342.
A shaft portion 341a extends in the extension direction of the rotating shaft 311 from the first joint portion 341 in the joint member 340. The shaft portion 341a is rotatably inserted into a through hole provided in the second joint portion 342.
Additionally, the first joint portion 341 has a first butting portion 341b that extends toward the second joint portion 342. The second joint portion 342 has a second butting portion 342a that extends toward the first joint portion 341.
One end 343a of the torsion spring 343 for a joint shown in
Additionally, the other end 343b of the torsion spring 343 for a joint is fixed to a projection 321 provided on the second member 320 that is integrated with the second joint portion 342. At this time, the torsion spring 343 for a joint is twisted such that an urging force in the direction of arrow L in which the second member 320 is brought close to the projection 341c of the first joint portion 341 is generated.
As shown in
With that, the description of the first member 310 and second member 320 that are coupled together by the joint member 340 will be ended, and then, the detector 330 in the detecting section 300 will be described.
As described above, the detector 330 is attached to the lower frame 201.
In the detector 330, a light emitting element 331 and a light receiving element 332 are arranged on a plate 201b within the lower frame 201 with the spacing therebetween. When the light emitted from the light emitting element 331 is detected by the light receiving element 332, the detector 330 outputs a signal indicating the event. A state where the detector 330 outputs a signal is referred to as an ON state, and a state where the detector does not output a signal is referred to as an OFF state.
In the detecting section 300 shown in
As shown in
As shown in
Next, in the ejector 200, the movement of the first member 310 and the second member 320 in the detecting section 300 when paper is transported on the internal ejector path 20a_1 that becomes a portion of the first transport path 20a shown in
Before paper is transported, the first member 310 of the detecting section 300 is in the first posture. As shown in
When the first member 310 takes the first posture and the second member 320 takes the OFF posture, paper is transported in the direction of arrow C shown in
When paper P transported in the direction of arrow C advances into the internal ejector path 20a_1, the detecting claw 312 of the first member 310 comes into contact with the paper P. As a result, the first member 310 rotates from the first posture shown
As described with reference to
When the first member 310 has rotated to the second posture, the second member 320 rotates to a posture (ON posture) where the light emitted from the light emitting element 331 in the detector 330 is passed to the light receiving element 332, bringing the detector 330 into the ON state.
As shown in
When the first member 310 rotates from the first posture shown in
Accordingly, the first member 310 returns to the first posture free of the contact with paper P at the timing where the trailing edge of the paper P has entered the internal ejector path 20a_1 and has passed the bottom of the detecting claw 312 in the direction of arrow C, i.e., at the timing where the paper P has arrived at the reversal position.
In this way, in the present exemplary embodiment, the returning of the first member 310 is performed reliably and rapidly compared to a case where, for example, the torsion spring 350 for a detecting claw is not present, and the return from the second posture to the first posture is performed, for example, due to the weight of the detecting claw 312.
Here, the torsion spring 350 for a detecting claw is arranged at one end of the rotating shaft 311 on the detecting claw 312 side.
It is supposed that the torsion spring 350 for a detecting claw is arranged at the other end of the rotating shaft 311 opposite to the detecting claw 312 side. In this case, a mechanism for allowing the torsion spring 350 for a detecting claw to urge the first member 310, without interfering with the movement of the joint member 340 shown in
In the present exemplary embodiment, since the torsion spring 350 for a detecting claw is arranged at one end of the rotating shaft 311 on the detecting claw 312 side, the above mechanism is not required, and the structure for return becomes simple compared to the case where the torsion spring 350 for a detecting claw is arranged at the other end.
The movement of return of the first member 310 is also transmitted to the second member 320 via the joint member 340, and the first member 310 returns, and simultaneously the second member 320 also rotates to the OFF posture from the ON posture. The detector 330 is brought into the OFF state at the timing when the second member 320 has rotated to the OFF posture.
In addition, in the present exemplary embodiment, the second member 320 has a larger thickness on the tip side than the thickness of a root portion on the rotating shaft 311 side as described above. For this reason, the second member 320 has a center of gravity at a position farther from the rotating shaft 311 than a middle point of a line segment that connects the rotating shaft 311 and a tip farthest from the rotating shaft 311 in the radial direction. In this way, the center of gravity of the second member 320 is closer to the tip side. The second member 320 that has rotated to the OFF posture hits the plate 201b shown in
When the output form set in the setting signal input to the control section 21 from the document reader 10 shown in
On the other hand, when the output form set in the setting signal is double-sided printing, the paper ejection roller 203 is reversed by the control section 21 at the timing when the detector 330 that has been once brought into the ON state is brought into the OFF state. Then, the paper P is at this point transported in a direction opposite to the direction of arrow C inside the internal ejector path 20a_1.
Paper P is transported in the direction of arrow E that is a direction opposite to the direction of arrow C shown in
Here, as described with reference to
Additionally, as described with reference to
As described above, since the second member 320 is not moved in the same direction as the movement of the first member 310, the second joint portion 342 integral with the second member 320 are not allowed to move in this direction.
On the other hand, the movement of the first member 310 is a movement to rotate the first joint portion 341 integral with the first member 310 with respect to the second joint portion 342, in a direction in which the first butting portion 341b separates from the second butting portion 342a.
Although the torsion spring 343 for a joint butts the first butting portion 341b against the second butting portion 342a by an urging force, in the present exemplary embodiment, the urging force is weaker than a force when the detecting claw 312 comes into contact with paper P and the first member 310 rotates to the third posture from the first posture.
Accordingly, when the first member 310 rotates from the first posture to the third posture, the first joint portion 341 idles with respect to the second member 320 and second joint portion 342 that are not allowed to move as described above.
As a result, when the first member 310 rotates from the first posture to the third posture, the posture of the second member 320 in the detecting section 300 is kept in the OFF posture shown in
In the detecting section 300, when the first member 310 rotates in the direction of arrow E from the first posture to the third posture, as described above, in the joint member 340, the first joint portion 341 idles with respect to the second joint portion 342. That is, the joint member 340 does not transmit the movement of the first member 310, which rotates from the first posture to the third posture, to the second member 320, and keeps the second member 320 in the OFF posture.
Here, when the first member 310 comes into contact with the reversed paper P and rotates, if the second member 320 also rotates and takes the ON posture, the detector 330 shown in
In the present exemplary embodiment, as described above, since the posture of the second member 320 is kept in the OFF posture at the time of paper reversal, the detector 330 is also kept in the OFF state at the time of paper reversal. Accordingly, the process for distinguishing the above two kinds of ON states is not required, and the processing in the control section 21 of
Here, when the first member 310 rotates from the first posture to the third posture, the torsion spring 350 for a detecting claw is contracted, and an urging force that returns the first member 310 to the first posture is generated in the torsion spring 350 for a detecting claw.
Additionally the torsion spring 343 for a joint in the joint member 340 urges the first butting portion 341b of the first joint portion 341 in a direction in which the first butting portion 341b is butted against the second butting portion 342a of the second joint portion 342. That is, the torsion spring 343 for a joint urges the first member 310 integral with the first joint portion 341 to the second member 320 side integral with the second joint portion 342. The urging force of the torsion spring 343 for a joint of that directs the first member 310 to the second member 320 side is also equivalent to the urging force that returns the first member 310 to the first posture.
Accordingly, the first member 310 returns to the first posture by a resultant force of the urging force of the torsion spring 350 for a detecting claw, and the urging force of the torsion spring 343 for a joint, at the tinning when the paper P transported in the direction of arrow E as shown in
The first member 310 that has returned to the first posture tends to rotate to the second posture side beyond the first posture due to inertia. The movement of the first member 310 is a movement to rotate the second member 320 to the ON posture. However, since the center of gravity of the second member 320 is closer to the tip side as described above, the movement of the second member 320, and consequently, the movement of the first member 310 itself caused by inertia are suppressed.
In the detecting section 300, the first member 310 that changes posture thereof among the first posture, the second posture and the third posture is equivalent to an example of the first member in the exemplary embodiments of the invention. Additionally, the rotating shaft 311 in the first member 310 is equivalent to an example of the rotating shaft in the exemplary embodiments of the invention, and the detecting claw 312 in the first member 310 is equivalent to an example of the detecting claw in the exemplary embodiments of the invention.
Additionally, in the detecting section 300, the second member 320 that changes posture thereof between the ON posture and the OFF posture is equivalent to an example of the second member in the exemplary embodiments of the invention. Additionally, the OFF posture of the second member 320 is equivalent to an example of a fourth posture in the exemplary embodiments of the invention, and the ON posture of the second member 320 is equivalent to an example of a fifth posture in the exemplary embodiments of the invention.
Additionally, in the detecting section 300, the joint member 340 that couples the first member 310 and the second member 320 together is equivalent to an example of a joint member in the exemplary embodiments of the invention.
Additionally, in the detecting section 300, the torsion spring 350 for a detecting claw that urges and returns the first member 310 toward the first posture from the second posture is equivalent to an example of an urging member in the exemplary embodiments of the invention.
Next, in a case where paper P is jammed between the fixing device 100 and the ejector 200 in the image forming apparatus 20 shown in
As described with reference to
A typical example of paper jamming between the fixing device 100 and the ejector 200 is schematically shown in
When such paper P is removed, as shown also in
Here, in the present exemplary embodiment, the first member 310 in the detecting section 300 is arranged closer to the reversal position than the branch point 20b between the first transport path 20a and the second transport path 20b.
As described above, the detecting claw 312 of the first member 310 is arranged at the longitudinal center of the ejector 200 shown in
In the present exemplary embodiment, since the first member 310 is arranged closer to the reversal position side than the branch point 20b, the detecting claw 312 is away from the working place of the user who is going to remove paper P. Accordingly, in the present exemplary embodiment, a situation where the detecting claw 312 becomes an obstacle to paper removal as described above is avoided.
In addition, in the present exemplary embodiment, as described with reference to
Additionally, in the present exemplary embodiment, the return of the first member 310 from the third posture to the first posture is performed by a resultant force of the urging force of the torsion spring 350 for a detecting claw and the urging force of the torsion spring 343 for a joint. However, the first member in the exemplary embodiments of the invention is not limited to this form. Additionally, in the present exemplary embodiment, the return of the first member from the third posture to the first posture is performed by only the urging force of the torsion spring 350 for a detecting claw.
Additionally, in the present exemplary embodiment, both the return of the first member 310 from the second posture to the first posture and the return of the first member from the third posture to the first posture are performed by the urging force of the torsion spring. However, the first member in the exemplary embodiments of the invention is not limited to this form. The first member in the exemplary embodiments of the invention may be a form in which the return of the first member to the first posture is performed, for example, by the weight of the detecting claw.
Additionally, in the present exemplary embodiment, the timing when the first member has returned to the first posture from the second posture is set to the timing when paper P has arrived at the reversal position. However, the invention is not limited thereto. The timing after a predetermined period after the first member returns to the first posture from the second posture may be set to the reversal position.
Additionally, in the present exemplary embodiment, the copying machine 1 has been illustrated as the image forming apparatus in the exemplary embodiments of the invention. However, the image forming apparatus of the invention may not be limited thereto, and may be a printer, facsimile, or the like.
The foregoing description of the exemplary embodiments of the present invention has been provided for the purposes of illustration and description. It is not intended to be exhaustive or to limit the invention to the precise forms disclosed. Obviously, many modifications and variations will be apparent to practitioners skilled in the art. The embodiments were chosen and described in order to best explain the principles of the invention and its practical applications, thereby enabling others skilled in the art to understand the invention for various embodiments and with the various modifications as are suited to the particular use contemplated. It is intended that the scope of the invention be defined by the following claims and their equivalents.
Number | Date | Country | Kind |
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2011-069697 | Mar 2011 | JP | national |