This application claims priority based on 35 USC 119 from prior Japanese patent application no. 2016-169284 filed on Aug. 31, 2016, the entire contents of which are incorporated herein by reference.
The disclosure relates to an image formation system which forms an image on a medium, and a medium transport apparatus and a medium feeder which are installed in the image formation system.
Some of image formation apparatuses, such as copiers, printers and facsimile machines, are designed such that an external medium feeder is attachable to them. An external medium feeder is attached to an attachment section of an image formation apparatus before print operation (see Patent Document 1: U.S. Pat. No. 8,490,964, for example).
An operation of attaching the medium feeder to the image formation apparatus is desired to be done smoothly while avoiding their collision.
To this end, there are demands for: a medium feeder smoothly attachable to an image formation apparatus; an image formation system including such a medium feeder; and a medium transport apparatus suitable for the medium feeder and the image formation system.
A medium transport apparatus in one or more embodiments may include: a frame; a table including a placement surface on which a medium is placed, a first end portion, and a second end portion, the table extending from the first end portion to the second end portion and being rotatable about a first shaft portion parallel to the placement surface; a first rotor arranged adjacent to the first end portion of the table; a second rotor arranged adjacent to the second end portion of the table; a belt that is stretched by the first rotor and the second rotor, and is configured to rotate circularly and to transport the medium in a first direction from the first end portion toward the second end portion; and a biasing part that links the frame and an attachment part provided between the second end portion and the first end portion of the table, and that biases the table.
A medium feeder in one or more embodiments may include: a medium separator including a stacker that holds media as stacked one on another, and a separation part that separates the media one by one, and a medium transport apparatus that transports a medium separated from the media by the medium separator. The medium transport apparatus includes: a frame; a table including a placement surface on which the medium is placed, a first end portion and a second end portion, the table extending from the first end portion to the second portion and being rotatable about a first shaft portion parallel to the placement surface; a first rotor arranged adjacent to the first end portion of the table; a second rotor arranged adjacent to the second end portion of the table; a belt that is stretched by the first rotor and the second rotor, and is configured to rotate circularly and to transport the medium in a first direction from the first end portion toward the second end portion; and a biasing part that links the frame and an attachment part between the second end portion and the first end portion of the table, and that biases the table. In addition, an image formation system in one or more embodiments may include: a medium feeder; and an image formation apparatus. The medium feeder includes: a medium separator includes: a stacker that holds media as stacked one on another, and a separation part that separates a medium from the media on a one-by-one basis, and a medium transport apparatus that transports the medium separated from the media by the medium separator, and the medium transport apparatus includes: a frame, a table including a placement surface on which the medium is placed, a first end portion and a second end portion, the table extending from the first end portion to the second portion and being rotatable about a first shaft portion parallel to the placement surface, a first rotor arranged adjacent to the first end portion of the table, a second rotor arranged adjacent to the second end portion of the table, a belt that is stretched by the first rotor and the second rotor, and is configured to rotate circularly and to transport the medium in a first direction from the first end portion toward the second end portion, and a biasing part that links the frame and an attachment part located between the second end portion and the first end portion in the table and which biases the table.
In the medium transport apparatus, the medium feeder and the image formation system as one or more embodiments may include the biasing part which biases part of the table upward. Accordingly, even in a case where the table is bulky in size and weight, the table can be attached to an attached part of the image formation apparatus relatively easily while avoiding the table's unnecessary collision with surroundings.
The medium transport apparatus and the medium feeder as one or more embodiments can be smoothly attached to the image formation apparatus. In addition, the image formation apparatus as one or more embodiments enables such a medium transport apparatus and such a medium feeder to be smoothly attached to the image formation apparatus.
Embodiments of the invention are hereinbelow explained in detail with reference to drawings. Incidentally, the following explanations are provided for one specific example of the invention. The invention is not limited to the below-explained aspects. In addition, the invention is not limited by arrangements, dimensions, dimensional ratios and the like of the components illustrated in the drawings. The explanations are provided in the following sequence.
[1.1 Overall Configuration of Image Formation System]
[1.2 Detailed Configuration of Medium Feeder S1]
Medium separator S11 includes bridge 2005 in addition to stacker 2020 and separation part 10, which are discussed above. Stacker 2020 and separation part 10 are adjacently arranged with bridge 2005 interposed in between. Stacker 2020 and separation part 10 are attached to bridge 2005.
(Configuration of Stacker 2020)
Stacker 2020, for example, includes: bottom plate 2020S which supports stacked media PM1 from below; stack guide 2021 which guides the rear ends of stacked media PM1; and set guides 2022 which guides the side ends of media PM1.
(Configuration of Separation Part 10)
Separation part 10 includes separation section 2001 and feed transport section 2010.
(Separation Section 2001)
Separation section 2001 includes separation frame 2002, separator 2003, knob 2004, separator frame 2006 and support 2025. Separation frame 2002 is fixed to bridge 2005 with the assistance of connector 2024, and holds support 2025 movable in the Y-axis direction. As illustrated in
(Feed Transport Section 2010)
Feed transport section 2010 is located lower than stacker 2020 and separation section 2001, and includes, for example, feed belt 2011, medium sensor 2012, drive roller 2013 and stretch roller 2014. Feed belt 2011 is an endless belt member stretched by drive roller 2013 and stretch roller 2014 which both extend in the Z-axis direction. Drive force is transmitted to drive roller 2013 from drive motor S1M which drives under the control of controller SS1, and thus, drive roller 2013 rotationally drives in an arrow R13 direction (
(Configuration of Bridge 2005)
Moreover, bridge 2005 includes: load guide 2027 which comes into contact with front end surfaces of media PM1 (see
(Configuration of Medium Transport Apparatus S12)
As illustrated in
Transport table 2033 is a member on which media PM1 are placed after separated by medium separator S11, and which guides thus-placed media PM1 to image formation apparatus S2. Transport table 2033 is a flat plate-shaped member which, for example, includes: placement surface 33S extending on the X-Z plane; end portion 33T1 located upstream: and end portion 33T2 located downstream. Transport table 2033 is provided turnable about shaft portion J1 (
Drive roller 2032 is a rotor arranged adjacent to, near, or close to end portion 33T1 of transport table 2033, and is a specific example corresponding to a “first rotor” in one or more embodiments. Drive force is transmitted to drive roller 2032 from drive motor S1M which drives under the control of controller SS1, and thus, drive roller 2032 rotationally drives about shaft portion J1, which extends in the Z-axis direction, in an arrow R32 direction (
Stretch roller 2037 is a rotor arranged adjacent to, near, or close to end portion 33T2 of transport table 2033, and is a specific example corresponding to a “second rotor” in one or more embodiments. Stretch roller 2037 is located in a distal end portion of medium transport apparatus S12. When medium transport apparatus S12 is attached to attached part 600, stretch roller 2037 is inserted into opening 650 of attached part 600.
Transport belt 2031 is an endless belt member stretched by drive roller 2032 and stretch roller 2037 so as to surround part of transport table 2033 or pass above placement surface 33S. Rotation of drive roller 2032 circularly rotates transport belt 2031 in a direction indicated with arrow R31 (
Furthermore, transport rollers 2034 are rotors which rotate, for example, about their axes each extending in the Z-axis direction, and are provided along the transport direction of media PM1 (X-axis direction) while facing transport belt 2031 and transport table 2033. Transport rollers 2034 rotate in response to the circular rotation of transport belt 2031 with medium PM1 held between transport rollers 2034 and transport belt 2031. Thereby, transport rollers 2034 transport medium PM1 to image formation apparatus S2. Transport roller frame 2039 holds respective transport rollers 2034 rotatable. Frame 2015 holds transport roller frame 2039 movable. Endmost transport roller 2034, which is the closest to end portion 33T2, is movable to be away from transport belt 2031 (or placement surface 33S). More specifically, for example, frame 2015 holds transport roller frame 2039 so that transport roller frame 2039 can turn in an arrow R39 direction about rotational shaft J39 provided to a rear end portion of transport roller frame 2039 (
Medium sensor 2035 is provided adjacent to, near, or close to a distal end of feed transport section 2010 (adjacent to, near, or close to stretch roller 2037). Medium sensor 2036 is provided in a middle position (between drive roller 2032 and stretch roller 2037) in the X-axis direction.
Medium transport apparatus S12 further includes a pair of first guide rollers 2040 and a pair of second guide rollers 2042 which are provided at positions on transport table 2033 different from one another in both the X-axis direction and the Z-axis direction. For example, first guide rollers 2040 are provided respectively to two ends of transport table 2033 in the Z-axis direction. Second guide rollers 2042 are provided between first guide rollers 2040 and are located next to each other in the Z-axis direction. First guide rollers 2040 are provided to a pair of frames 2041 which are fixed to transport table 2033. Second guide rollers 2042 are provided to frame 2043 which links the pair of frames 2041 together.
Medium transport apparatus S12 further includes biasing part 2044. Biasing part 2044 links or connects frame 2015 and attachment part 2015T provided between end portion 33T2 and shaft portion J1 in transport table 2033, and thereby urges transport table 2033 upward. In other words, transport table 2033 includes attachment part 2015T provided between second end portion 33T2 and end portion 33T1 in X-axis direction. Biasing part 2044 connecting frame 2015 and attachment part 2015T biases transport table 2033 in a longitudinal direction of biasing part 2044. Biasing part 2044 is, for example, an elastic member such as a coil spring or a leaf spring. Hung by biasing part 2044, transport table 2033 is elastically turnable about shaft portion J1.
[1.3 Detailed Configuration of Image Formation Apparatus S2]
Next, referring to
(Medium Feed Device 100)
Medium feed device 100 includes feed tray 101, placement board 102, lift-up lever 103, motor 104, elevation detector 201, pickup roller 202, feed roller 203 and retard roller 204.
Feed tray 101, for example, is detachably attached to a lower part of image formation apparatus S2, contains media PM2 as stacked, and is provided with placement board 102 so that placement board 102 is turnable about shaft J102. Some of media PM2 are stacked on placement board 102. Lift-up lever 103, which is supported turnable by shaft J103, is provided to a feed-out side of feed tray 101 from which media PM2 are fed out. Drive force from motor 104 rotates shaft J103. For example, based on a signal from controller SS2, motor 104 operates and stops. In medium feed device 100 like this, lift-up lever 103 turns about shaft J103; thereby, a distal end portion of lift-up lever 103 pushes placement board 102 upward; and media PM2 placed on placement board 102 also rise. This configuration makes sure that the upper surface of the uppermost one of media PM2 is in contact with pickup roller 202. Elevation detector 201 detects that placement board 102 is elevated sufficiently up to a predetermined height and the upper surface of the uppermost one of media PM2 comes into contact with pickup roller 202. Based on a signal from elevation detector 201, controller SS2 stops the drive of motor 104. Pickup roller 202, feed roller 203 and retard roller 204 jointly function as a print medium feed-out section which feeds media PM2, contained in feed tray 101, to transport device 300 on a one-by-one basis. Pickup roller 202 and feed roller 203 are rotationally driven in their respective arrow directions illustrated in
(Attached Part 600)
Attached part 600 receives medium PM1 transported from medium transport apparatus S12 in medium feeder S1, and includes opening 650 provided in the side surface of housing K.
Guide surface 605 guides first guide rollers 2040 and second guide rollers 2042 to the deep of attached part 600 while biasing first guide rollers 2040 and second guide rollers 2042 downward. Guide surface 605 includes slope portion 605A, slope portion 605B, flat surface portion 605C and slope portion 605D in this order from opening 650 to the downstream. Slope portion 605B and flat surface portion 605C jointly form protrusion T605. Protrusion T605 is provided only in a middle portion between the pair of second guide rollers 2042 in the width direction of medium PM1 (in the Z-axis direction). Thus, when medium transport apparatus S12 is attached to attached part 600, the pair of first guide rollers 2040 do not come into contact with protrusion T605, and only the pair of second guide rollers 2042 come into contact with protrusion T605.
It should be noted that pickup rollers 202, 602 and feed rollers 203, 603 each may include, for example, a built-in one-way clutch mechanism such that the rollers are idly rotatable in the directions indicated with the arrows, respectively. Furthermore, using rotational torque generators, retard rollers 204, 604 generate rotational torque in their respective arrow directions illustrated in
(Transport Device 300)
Transport device 300 is a mechanism which transports media PM2 from medium feed device 100, or media PM1 from medium transport apparatus S12, to a transfer device on a one-by-one basis. Transport device 300 includes, for example, medium sensor 301, transport roller pair 302, medium sensor 303, transport roller pair 304, medium thickness sensor 320, medium sensor 330, and transport roller pair 305 which are arranged in this order from the upstream to the downstream. Transport roller pairs 302, 304, 305 transport medium PM1, PM2 to the downstream while restricting the skew of medium PM1, PM2 or preventing medium PM1, PM2 from taking an oblique course. Medium PM1 from attached part 600 flow into the transport passage at an area between transport roller pair 302 and transport roller pair 304. Medium sensors 301, 303, 330 detect the positions of medium PM1, PM2 in order to adjust timings of driving transport roller pairs 302, 304, 305.
(Image Formation Device 400)
Image formation device 400 includes, for example, image formation units 400Y, 400M, 400C, 400K. Using their corresponding color toners, that is, a yellow toner, a magenta toner, a cyan toner and a black toner, image formation units 400Y, 400M, 400C, 400K form their respective color toner images, which are specific examples of a developer image.
Image formation units 400Y, 400M, 400C, 400K each include, for example, photosensitive drum 401, charge roller 402, light emitting diode (LED) head 850, development roller 404, cleaning part 405, toner containers 406Y, 406M, 406C, 406K, and supply roller 407. Charge roller 402, development roller 404 and supply roller 407 jointly form a development unit, and work under the control of controller SS2.
Photosensitive drum 401 is a column-shaped member which carries an electrostatic latent image on its surface (surface part), and which extends in the Z-axis direction. Photosensitive drum 401 includes a photoreceptor (for example, an organic photoreceptor). More specifically, photosensitive drum 401 includes a conductive support, and a photoconductive layer covering the circumference (surface) of the conductive support. The conductive support is formed, for example, from a metal pipe which is made of aluminum. The photoconductive layer has, for example, a structure in which a charge generation layer and a charge transport layer are stacked sequentially. Photosensitive drum 401 like this rotates at a predetermined circumferential speed (in this example, rotates counterclockwise as indicated with the corresponding arrow in
Charge roller 402 is a member (charge member) which electrically charges the surface (surface part) of photosensitive drum 401, and which is arranged in contact with the surface (circumferential surface) of photosensitive drum 401. Charge roller 402 includes, for example, a metal shaft, and a semi-conductive rubber layer (for example, a semi-conductive epichlorohydrin rubber layer) covering the circumference (surface) of the metal shaft. In this example, charge roller 402 rotates clockwise (rotates in a direction opposite to the direction in which photosensitive drum 401 rotates).
Development roller 404 is a member that carries the toner, which is used to develop the electrostatic latent image, on its surface. Development roller 404 is arranged in contact with the surface (circumferential surface) of photosensitive drum 401. Development roller 404 includes, for example, a metal shaft, and a semi-conductive urethane rubber layer covering the circumference (surface) of the metal shaft. Development roller 404 like this rotates at a predetermined circumferential speed (in this example, rotates clockwise, that is, in the direction opposite to the direction in which photosensitive drum 401 rotates).
Toner containers 406Y, 406M, 406C, 406K respectively contain the yellow toner, the magenta toner, the cyan toner and the black toner, as well as supply the respective color toners to corresponding supply rollers 407 depending on the necessity.
Each of supply rollers 407 is a member (supply member) which supplies the color toner to development roller 404, and are arranged in contact with the surface (circumferential surfaces) of development roller 404. Supply roller 407 includes, for example, a metal shaft, and a foamed silicone rubber layer covering the circumference (surface) of the metal shaft. In this example, supply roller 407 rotates clockwise (rotates in the same direction as development roller 404 rotates).
Each LED head 850 is a light exposure device which forms electrostatic latent images on the surface (surface part) of photosensitive drum 401 by exposing the surface of photosensitive drum 401 to light. Each LED head 850 includes light emitting portions which are in charge of corresponding photosensitive drum 401, and which are arranged in the Z-axis direction. Each LED head 850 includes, for example, a light source such as a light emitting diode which emits irradiation light, and a lens array which forms an image of the irradiation light on the surface of photosensitive drum 401.
Cleaning part 405 removes toner which remains on the surface of photosensitive drum 401 after a toner image is transferred onto medium PM1, PM2.
(Intermediate Transfer Device 700)
Intermediate transfer device 700 is also termed an intermediate transfer belt unit, and includes intermediate transfer belt 701, drive roller 702, driven roller 703, backup roller 704, primary transfer rollers 705Y, 705M, 705C, 705K, cleaner 706, secondary transfer roller 707, and biasing part 708. Drive roller 702, driven roller 703, backup roller 704, primary transfer rollers 705Y, 705M, 705C, 705K, and secondary transfer roller 707 are substantially column-shaped members, which are rotatable about their respective rotational shaft portions extending in the Z-axis direction vertical to paper sheet surfaces. Intermediate transfer device 700 is a mechanism which transports medium PM1, PM2, transported from transport roller pair 305, in the transport direction, and which transfers the toner images, formed by image formation units 400Y, 400M, 400C, 400K, onto intermediate transfer belt 701 sequentially in the transport direction.
Intermediate transfer belt 701 is, for example, an endless elastic belt made of a resin material such as polyimide resin. Intermediate transfer belt 701 is provided stretched (suspended stretched) by drive roller 702, driven roller 703 and backup roller 704.
Motive power which is transmitted to drive roller 702 from drive motor S2M controlled by controller SS2 rotates drive roller 702 clockwise in the arrow direction illustrated in
Secondary transfer roller 707 and backup roller 704 jointly form secondary transfer section 750. Secondary transfer roller 707 and backup roller 704 are arranged facing each other with intermediate transfer belt 701 interposed in between. Secondary transfer roller 707 includes, for example, a metal core, and an elastic layer, such as a foamed rubber layer, formed by being wound around the circumferential surface of the metal core. A biasing part, such as a coil spring, whose one end is fixed to housing K or the like of image formation apparatus S2 biases secondary transfer roller 707 toward backup roller 704. Thereby, secondary transfer roller 707 is pressed against backup roller 704 with intermediate transfer belt 701 interposed in between.
When backup roller 704 and secondary transfer roller 707 transfer (secondarily transfer) toner images on intermediate transfer belt 701 onto medium PM1, PM2 supplied from transport roller pair 305, a DC voltage is applied to secondary transfer roller 707 to generate a potential difference between secondary transfer roller 707 and backup roller 704.
(Configuration of Fixation Device 500)
Fixation device 500 is a member to apply heat and pressure to the toner images transferred on medium PM1, PM2 having passed secondary transfer section 750 which includes secondary transfer roller 707 and backup roller 704, as well as to thereby fix the toner images to medium PM1, PM2. Fixation device 500 includes upper roller 501 and lower roller 502, as illustrated in
Upper roller 501 and lower roller 502 include heat sources 503A, 503B, which are heaters such as halogen lamps, therein, respectively. Upper roller 501 and lower roller 502 function as heat rollers which apply heat to the toner images on medium PM1, PM2. For example, upper roller 501 is rotationally driven by drive motor S2M controlled by controller SS2. Heat sources 503A, 503B are supplied with bias voltages controlled by controller SS2, and thus control the surface temperatures of upper roller 501 and lower roller 502, respectively.
Lower roller 502 is arranged facing upper roller 501 so as to form a press-contact portion between lower roller 502 and upper roller 501. Lower roller 502 functions as a pressure roller which applies pressure to the toner images on medium PM1, PM2. Lower roller 502 may include a surface layer made of an elastic material.
(Delivery Device 800)
Delivery device 800 includes, for example, transport roller pairs 801 to 804, and stacker 805. Thus, when delivery separator 901 (described later) is oriented as illustrated in
(Reverse Device 900)
Reverse Device 900 is a mechanism which, after the images are formed on the surface of medium PM1, PM2, forms a transport passage for guiding medium PM1, PM2 from transport roller pair 305 to secondary transfer section 750 and fixation device 500 once again in order to form images on the back surface of medium PM1, PM2. Reverse device 900 includes delivery separator 901, reverse roller pair 902, reverse separator 903, guide part 904, transport roller pairs 905 to 907 and evacuation part 914.
When delivery separator 901 is switched, for example, into a switch-back orientation indicated with dashed lines in
[1.4 Working/Effects of Image Formation System]
(A. Basic Operation)
The image formation system transfers toner images onto medium PM1, PM2 in the following way.
Once print image data is inputted into activated image formation apparatus S2 from an external apparatus, controller SS2 starts an operation of printing the print image data.
More specifically, controller SS2 drives intermediate transfer belt 701 and each photosensitive drum 401, as well as makes each charge roller 402 start a charge operation. In addition, controller SS2 sends a light-exposure control signal to each LED head 850. At a timing specified by the light-exposure control signal, LED head 850 irradiates photosensitive drum 401 with light corresponding to a color component of a print image, and thereby forms an electrostatic latent image on the surface of photosensitive drum 401. Development roller 404 forms a toner image as a developer image in the corresponding one of yellow (Y), magenta (M), cyan (C) and black (B) by sticking a corresponding developer to the electrostatic latent image on photosensitive drum 401. A power supply circuit in controller SS2 applies transfer biases to primary transfer rollers 705Y, 705M, 705C, 705K. Thus, primary transfer rollers 705Y, 705M, 705C, 705K sequentially transfer the toner images on photosensitive drums 401 onto the transferred surface of intermediate transfer belt 701, and thereby superimpose the toner images.
Subsequently, controller SS2 rotates pickup rollers 202, 602 and feed rollers 203, 603, as well as makes medium feeder S1 start to supply medium PM1, PM2 by sending a control signal to controller SS1 in medium feeder S1. Thereby, medium PM1, PM2 is supplied to transport device 300 at a predetermined transport speed. More specifically, the supply of media PM2 is achieved as follows. As illustrated in
For example, once medium sensor 330 detects the position of medium PM1, PM2, medium sensor 330 sends a detection signal to controller SS2. Controller SS2 adjusts the transport speed of medium PM1, PM2 and the rotation speed of intermediate transfer belt 701, and thus aligns medium PM1, PM2 with the toner images on intermediate transfer belt 701. Thereby, at a secondary transfer position, that is, at a position where backup roller 704 and secondary transfer roller 707 face each other, the toner images on intermediate transfer belt 701 are secondarily transferred onto predetermined areas on medium PM1, PM2. Thereafter, fixation device 500 applies heat and pressure to the toner images having been transferred onto medium PM1, PM2, and thus fixes the toner images to medium PM1, PM2. Eventually, transport roller pairs 801 to 804 and the like in delivery device 800 deliver medium PM1, PM2 with the toner images fixed thereto to the outside, and medium PM1, PM2 is accumulated on stacker 805.
(B. Attachment Operation of Medium Feeder S1)
Next, referring to
As illustrated in
Next, as illustrated in
(C. Operation of Medium Feeder S1)
Next, referring to
The drive of drive motor S1M rotationally drives drive roller 2013 in the arrow R13 direction (
The drive of drive motor S1M rotationally drives drive roller 2032 in the arrow R32 direction (
(D. Working/Effects of Image Formation System)
As discussed above, in the embodiment, biasing part 2044 biases the part of transfer table 2033 upward in medium feeder S1. For this reason, even if transport table 2033 is bulky in size and weight, medium transport apparatus S12, including transport table 2033, can be attached to attached part 600 of image formation apparatus S2 relatively easily while avoiding medium transport apparatus S12, including transport table 2033, unnecessarily colliding with guide plates 608, medium load plate 601 and the like in attached part 600. In other words, medium transport apparatus S12 (medium feeder S1) of the embodiment can be attached to image formation apparatus S2 smoothly.
Particularly in the embodiment, since guide surface 605 in attached part 600 guides first guide rollers 2040 and second guide rollers 2042 while biasing first guide rollers 2040 and second guide rollers 2042 downward, medium transport apparatus S12 imposes no excessive load on medium load plate 601 or the like in attached part 600.
In contrast to this, if the structure were, for example, such that first guide rollers 2040 and second guide rollers 2042 are biased and guided upward by medium load plate 601 and the like while contacting medium load plate 601 and the like, medium load plate 601 and the like would likely be deformed (warped) by the weight of medium transport apparatus S12 in a case where transport table 2033 is very heavy. Accordingly, attached part 600 would likely deteriorate quickly, and the accurate guide would likely be hindered. With these taken into consideration, it is more desirable that, like in the embodiment, first guide rollers 2040 and second guide rollers 2042 be biased and guided downward by guide surface 605 located above first guide rollers 2040 and second guide rollers 2042 while contacting guide surface 605.
Although described using embodiments, the invention is not limited to the foregoing embodiment, and can be modified variously. For example, although the foregoing embodiment has described the image formation apparatus which forms a color image, the invention is not limited to this. The image formation apparatus may be, for example, one which forms a monochrome image by transferring only a black toner image. Furthermore, although the foregoing embodiment has described the image formation apparatus which performs the secondary transfer, the invention is also applicable to an image formation apparatus which performs primary transfer (direct transfer).
Moreover, although in the foregoing embodiment, transport table 2033 is hung from the side wall portion of frame 2015 by biasing part 2044, the invention is not limited to this mode. Transport table 2033 may be, for example, pushed upward by biasing part 2044 from below.
Besides, although in the foregoing embodiment and the like, both the table (transport table 2033) and the first rotor (drive roller 2032) rotate about the first shaft portion (shaft portion J1), the invention is not limited to this. The table (transport table 2033) and the first rotor (drive roller 2032) may rotate about their respective shaft portions which are different from each other. What is more, the positions of drive roller 2032 and stretch roller 2037 may be swapped for each other so that transport table 2033 and stretch roller 2037 rotate about the same rotational shaft portion.
In addition, although in the foregoing embodiment and the like, the LED heads each using the light emitting diode as the light source are used as the light exposure devices, the light exposure devices each may use, for example, a laser device or the like as the light source instead.
Furthermore, although the foregoing embodiment and the like have described the image formation apparatus including the print function which is a specific example of the “image formation apparatus” in one or more embodiments, the “image formation apparatus” is not limited to this. In other words, the invention is applicable to an image formation apparatus to function as a multi-function printer which, for example, has a scan function and a facsimile function in addition to such a print function.
Number | Date | Country | Kind |
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2016-169284 | Aug 2016 | JP | national |
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Number | Date | Country | |
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20180059609 A1 | Mar 2018 | US |