The entire disclosure of Japanese Patent Application No. 2018-050984, filed on Mar. 19, 2018 is incorporated herein by reference in its entirety.
The present disclosure relates to an image formation apparatus, and more specifically to an image formation apparatus which transfers a toner image formed on an image carrier to a recording medium.
In an image formation apparatus provided with a secondary transfer roller of a type which is constantly pressed into contact with an intermediate transfer belt (or an image carrier), when a patch image is formed on the intermediate transfer belt, the patch image comes into contact with the secondary transfer roller at a secondary transfer position (or a nip) and the patch image's toner would adhere to the secondary transfer roller. When the secondary transfer roller has toner adhering thereto, and in that condition, next printing is performed on a sheet (or recording media) the sheet has a back surface smeared with the toner.
As a countermeasure against this, a first method is applied as follows: when a patch image comes into contact with the secondary transfer roller, a voltage identical in polarity to the toner is applied to the secondary transfer roller to prevent the toner from adhering to the secondary transfer roller. However, even if this first method is performed, some toner would adhere to the secondary transfer roller.
Accordingly, for example, Japanese Laid-Open Patent Publication No. 2013-105145 discloses a second method as follows: after the first method is performed, a positive voltage and a negative voltage are alternately and repeatedly applied to the secondary transfer roller to move the toner adhering to the secondary transfer roller to the intermediate transfer belt to thus clean the secondary transfer roller.
In the second method, however, a major portion of the toner adhering to the secondary transfer roller is electrically weakly charged and accordingly, not electrically movable, and the amount of toner which can be removed by applying voltage once is a small amount, so that it is necessary to apply voltage many times. This results in a long waiting time and may hence impair productivity.
A main object of the present invention is to provide an image formation apparatus which can prevent a recording medium from having a smeared back surface and thus achieve high productivity.
To achieve at least one of the abovementioned objects, according to an aspect of the present disclosure, an image formation apparatus reflecting one aspect of the present invention comprises: an image carrier rotatably driven and having a surface on which a toner image is formed; a first transfer roller cooperating with a surface of the image carrier to form a nip at a first position in a direction in which the image carrier rotates; a discharging member provided at a second position downstream of the nip in a direction in which the first transfer roller rotates; a first power supply that applies a first voltage opposite in polarity to toner to the first transfer roller to transfer the toner image to a recording medium when the recording medium is inserted in the nip; and a second power supply that applies a second voltage identical in polarity to the toner to the discharging member to cause an electric discharge to electrically charge the toner on a surface of the first transfer roller to electrically attract the toner to the first transfer roller.
The advantages and features provided by one or more embodiments of the invention will become more fully understood from the detailed description given hereinbelow and the appended drawings which are given by way of illustration only, and thus are not intended as a definition of the limits of the present invention.
Hereinafter, one or more embodiments of the present invention will be described with reference to the drawings. However, the scope of the invention is not limited to the disclosed embodiments.
In
Intermediate transfer belt 30 is tensioned and thus engaged on driven roller 38 and driving roller 39 horizontally. Driving roller 39 is connected to a motor (not shown). Intermediate transfer belt 30 and driven roller 38 are ganged with driving roller 39 and thus rotated.
Image forming units 1Y, 1M, 1C, and 1K are disposed under intermediate transfer belt 30 successively in a direction in which intermediate transfer belt 30 rotates. Toner bottles 15Y, 15M, 15C, and 15K contain toners of yellow (Y), magenta (M), cyan (C), and black (BK), respectively.
Image forming unit 1Y receives toner supplied front toner bottle 15Y to form a yellow toner image. Image forming unit 1M receives toner supplied from toner bottle 15M to form a magenta toner image. Image forming unit 1C receives toner supplied from toner bottle 15C to form a cyan toner image. Image forming unit 1K receives toner supplied from toner bottle 15K to form a black toner image.
Image forming units 1Y, 1M, 1C, and 1K each include a photoreceptor 10, a charger 11, an exposure unit 12, a developing unit 13, and a cleaning blade 17. Charger 11 electrically charges a surface of photoreceptor 10 uniformly. Exposure unit 12 operates in response to a control signal received from control device 51 to emit a laser beam to photoreceptor 10 to expose a surface of photoreceptor 10 to light according to an input image pattern. Thus, an electrostatic latent image corresponding to an input image is formed on the surface of photoreceptor 10.
Developing unit 13 applies a developing bias to a developing roller 14 while rotating developing roller 14 to cause toner to adhere to a surface of developing roller 14. Thus, the electrically charged toner is transferred from developing roller 14 to photoreceptor 10, and a toner image depending on an electrostatic latent image is developed on a surface of photoreceptor 10. Photoreceptor 10 and a surface of intermediate transfer belt 30 are in contact with each other.
Cleaning blade 17 is pressed into contact with photoreceptor 10. Cleaning blade 17 collects toner which remains on a surface of photoreceptor 10 after a toner image is transferred from photoreceptor 10 to intermediate transfer belt 30.
Primary transfer roller 31 is provided to correspond to each image forming unit 1, and is rotatably supported in contact with a back surface of intermediate transfer belt 30. Primary transfer roller 31 and photoreceptor 10 of image forming unit 1 associated therewith sandwich intermediate transfer belt 30. When a transferring voltage opposite in polarity to the toner image is applied to primarily transfer roller 31, the toner image is transferred from photoreceptor 10 to a surface of intermediate transfer belt 30.
A toner image of yellow (Y), a toner image of magenta (M), a toner image of cyan (C), and a toner image of black (BK) are superposed, one on another, sequentially and thus transferred from photoreceptor 10 to intermediate transfer belt 30. Thus, a color toner image is formed on a surface of intermediate transfer belt 30.
At a predetermined position (a first position) downstream of image forming unit 1K, secondary transfer roller 33 is rotatably supported in contact with a surface of intermediate transfer belt 30. Secondary transfer roller 33 and driving roller 39 sandwich intermediate transfer belt 30. Secondary transfer roller 33 and intermediate transfer belt 30 are in contact with each other, and a portion at which they are in contact with each other is referred to as a nip. When intermediate transfer belt 30 is rotatably driven, the toner image on the surface of intermediate transfer belt 30 is transported to the nip between secondary transfer roller 33 and intermediate transfer belt 30.
Discharging member 34 is provided at a predetermined position (a second position) downstream of the nip in the direction in which secondary transfer roller 33 rotates. Discharging member 34 is provided to electrically charge the toner adhering to the surface of secondary transfer roller 33 to electrically attract the toner to secondary transfer roller 33 to prevent paper S from having the back surface smeared therewith.
A large number of sheets S (or recording media) are set in cassette 37. Each sheet S is sent from cassette 37 by timing roller 40 along transport path 41 to the nip between secondary transfer roller 33 and intermediate transfer belt 30. Control device 51 controls a transferring voltage applied to secondary transfer roller 33 in accordance with a timing of sending out sheet S.
When sheet S is inserted between secondary transfer roller 33 and the toner image on the surface of intermediate transfer belt 30 and in that condition a transferring voltage opposite in polarity to the toner image is applied to secondary transfer roller 33, the toner image is attracted from intermediate transfer belt 30 toward secondary transfer roller 33 and thus transferred to a surface of sheet S. Timing to transport sheet S to secondary transfer roller 33 is controlled by timing roller 40 in accordance with the position of the toner image on intermediate transfer belt 30. As a consequence, the toner image on intermediate transfer belt 30 is transferred to an appropriate position on sheet S.
Sheet S with the toner image transferred thereon is sent to fixing device 50 located above. Fixing device 50 applies pressure to and heat sheet S passing therethrough. In response to a control signal from control device 51, fixing device 50 controls the degree of heating the sheet, the pressure applied to the sheet and the like. By fixing device 50 heating and applying pressure to sheet S, the toner image is fixed on sheet S. Subsequently, sheet S is discharged to tray 48.
Optical sensor 45 is provided to face a surface of intermediate transfer belt 30 at a predetermined position downstream of the nip between secondary transfer roller 33 and intermediate transfer belt 30. Optical sensor 45 senses in density a patch image formed on a surface of intermediate transfer belt 30 separately from a toner image. Control device 51 adjusts a developing bias voltage or the like, based on a detection result from optical sensor 45, to adjust a toner image in density.
Further, cleaning blade 42 is pressed against intermediate transfer belt 30 at a predetermined position (a third position) downstream of optical sensor 45. Cleaning blade 42 and driven roller 38 sandwich intermediate transfer belt 30. Cleaning blade 42 collects toner remaining on a surface of intermediate transfer belt 30 after a toner image is transferred from intermediate transfer belt 30 to sheet S. The recovered toner is transported by a transporting screw (not shown) and stored in a waste toner container (not shown).
When direct-current voltage VP1 opposite in polarity to the toner is applied to secondary transfer roller 33 while sheet S is inserted in nip NP, the toner image on the surface of intermediate transfer belt 30 is transferred to a surface of sheet S. While sheet S is not inserted into nip NP, direct-current voltage VN1 identical in polarity to the toner is applied to secondary transfer roller 33 to suppress adhesion of the toner to the surface of secondary transfer roller 33.
Direct-current power supply 62 is controlled by control device 51 to apply a control voltage VC2 to discharging member 34. When electrically weakly charged toner adheres to the surface of secondary transfer roller 33, control voltage VC2 is set to a large direct-current voltage VN2 identical in polarity to the toner, otherwise control voltage VC2 is set to 0 V. For example, when the toner is negative in polarity, direct-current voltage VN2 is a large negative voltage.
Discharging member 34 is provided in the form of a roller and includes, for example, a rotation shaft, a base layer provided on a circumference of the rotation shaft, and a surface layer provided to cover the outer circumferential surface of the base layer. The rotation shaft is formed of metal, for example, and receives control voltage VC2 from direct-current power supply 62. The base layer is formed of an electrically conductive, elastic body (for example, electrically conductive rubber). The surface layer is formed of electrically conductive resin.
Discharging member 34 is pressed against secondary transfer roller 33 with a predetermined force. Discharging member 34 and secondary transfer roller 33 configure a nip of a predetermined width. Discharging member 34 may be supported so as not to rotate, or it may be supported so as to rotate following secondary transfer roller 33.
Direct-current voltage VN2 is set to a large voltage (e.g., −2 kV to −3 kV) such that an electric discharge 63 is caused in small gaps on opposite sides of the nip between discharging member 34 and secondary transfer roller 33. In other words, in small gaps on opposite sides of the nip between discharging member 34 and secondary transfer roller 33, direct-current voltage VN2 is set to a voltage larger than Paschen's discharge starting voltage.
Therefore, when direct-current voltage VN2 is applied to discharging member 34, electric discharge 63 is caused in small spaces on opposite sides of the nip between discharging member 34 and secondary transfer roller 33. When electrically weakly charged toner Ta adhering to the surface of secondary transfer roller 33 passes between discharging member 34 and secondary transfer roller 33, electrically weakly charged toner Ta is exposed to electric discharge 63 and becomes electrically strongly charged toner Tb negative in polarity.
When direct-current voltage VP1 opposite in polarity to the toner is applied to secondary transfer roller 33 while sheet S is inserted in nip NP, electrically strongly charged toner Tb is electrically attracted to the surface of secondary transfer roller 33 and does not adhere to the back surface of sheet S. This can prevent the toner on the surface of secondary transfer roller 33 from smearing the back surface of sheet S.
With reference to
Patch images P1 and P2 are formed for adjusting a toner image in density and pass through nip NP without being transferred to sheet S. Patch images P1 and P2 have their density sensed by optical sensor 45 (see
The leading edges of toner images T1, T2, T3 reach nip NP at times t1, t6, t8, respectively, and the trailing edges thereof reach nip NP at times t2, t7, t9 respectively. The leading edges of patch images P1 and P2 both reach nip NP at time t3, and the trailing edges thereof both reach nip NP at time t4.
Three sheets S1, S2, S3 are sequentially supplied to nip NP, as timed to reach it when three toner images T1, T2, T3 do. Toner images T1, T2, T3 and sheets S1, S2, S3 are equal in size, respectively.
While sheets S1, S2 and S3 are inserted in nip NP (for example, for t1 to t2, t6 to t7, and t8 to t9), control voltage VC1 is set to large positive voltage VP1 opposite in polarity to the toner. As a result, toner images T1, T2, T3 on the surface of intermediate transfer belt 30 are transferred onto the surfaces of sheets S1, S2, S3, respectively.
While sheet S is not inserted in nip NP (for example, for t2 to t6, and t7 to t8), control voltage VC1 is set to small negative voltage VN1 identical in polarity to the toner. This suppresses adhesion of toner of patch images P1 and P2 or the like to the surface of secondary transfer roller 33. Note, however, that patch images P1 and P2 do come into contact with secondary transfer roller 33, and a small amount of toner adheres to the surface of secondary transfer roller 33. The toner adhering to the surface of secondary transfer roller 33 includes electrically weakly charged toner Ta (see
In response to the leading edges of patch images P1 and P2 having reached nip NP, control voltage VC2 is set to large direct-current voltage VN2 (for example, −2 kV to −3 kV) identical in polarity to the toner for a predetermined period of time.
When control voltage VC2 is set to direct-current voltage VN2, electric discharge 63 occurs on opposite sides of the nip between discharging member 34 and secondary transfer roller 33. When electrically weakly charged toner Ta adhering to the surface of secondary transfer roller 33 passes between discharging member 34 and secondary transfer roller 33, electrically weakly charged toner Ta is exposed to electric discharge 63 and becomes electrically strongly charged toner Tb negative in polarity (see
In
In
Thus, in the first embodiment, direct-current voltage VN2 identical in polarity to toner is applied to discharging member 34 to cause electric discharge 63 to electrically charge toner on a surface of secondary transfer roller 33 to electrically attract the toner to secondary transfer roller 33. This can prevent the toner adhering to secondary transfer roller 33 from smearing the back surface of sheet S. Further, printing can be done while attracting the toner to secondary transfer roller 33, and productivity is not impaired.
While in the first embodiment patch images P1 and P2 used for adjusting a toner image in density are formed between toner images T1 and T2, the present invention is not limited thereto. The present invention is also applicable to forming a patch image in order to: (1) discharge old toner in developing unit 13 and refresh a developing agent; (2) refresh the surface of photoreceptor 10 uniformly; (3) reduce friction between photoreceptor 10 and cleaning blade 17; and (4) reduce friction between intermediate transfer belt 30 and cleaning blade 42. For cases (1) to (4), the patch image is formed to have substantially the same width as intermediate transfer belt 30.
Further, the present invention is also applicable to a case in which patch images P1 and P2 are not formed between toner images T1 and T2. When toner adheres to a surface of secondary transfer roller 33 due to a sheet jam or the like, direct-current voltage VN2 identical in polarity to the toner can be applied to discharging member 34 to make the toner on the surface of secondary transfer roller 33 electrically strongly charged toner Tb. This also allows the toner on the surface of secondary transfer roller 33 to be electrically attracted to secondary transfer roller 33 to prevent the toner adhering to secondary transfer roller 33 from smearing the back surface of sheet S.
While in the first embodiment discharging member 34 is brought into contact with secondary transfer roller 33, discharging member 34 and secondary transfer roller 33 may be disposed in parallel with a predetermined small gap therebetween. In that case, direct-current voltage VN2 is set to a voltage larger than Paschen's discharge starting voltage to cause electric discharge 63 in the gap between discharging member 34 and secondary transfer roller 33. In this exemplary variation, discharging member 34 does not come into contact with secondary transfer roller 33, which can suppress adhesion of toner on the surface of secondary transfer roller 33 to discharging member 34.
Discharging member 34A is provided in the form of a sheet and includes, for example, a substrate, a base layer provided on a surface of the substrate, and a surface layer provided on a surface of the base layer. The substrate is formed of metal, for example, and receives control voltage VC2 from direct-current power supply 62. The base layer is formed of an electrically conductive, elastic body (for example, electrically conductive rubber). The surface layer is formed of electrically conductive resin.
Discharging member 3A has the surface layer with a tip end directed downstream in the direction in which secondary transfer roller 33 rotates, and pressed against a surface of secondary transfer roller 33 with a predetermined force. Discharging member 34A has a base end portion supported by a support member (not shown). Control voltage VC2 is applied to the base end portion of the substrate of discharging member 34A.
Discharging member 34A and secondary transfer roller 33 configure a nip having a predetermined width. Direct-current voltage VN2 is set to a large voltage (e.g., −2 kV to −3 kV) such that electric discharge 63 is caused in a small gap near the nip between discharging member 34A and secondary transfer roller 33. In other words, in a small gap near the nip between discharging member 3A and secondary transfer roller 33, direct-current voltage VN2 is set to a voltage larger than Paschen's discharge starting voltage.
When direct-current voltage VN2 identical in polarity to the toner is applied to discharging member MA, electric discharge 63 occurs in a gap between discharging member 3A and secondary transfer roller 33, and when electrically weakly charged toner Ta on the surface of secondary transfer roller 33 passes through the electrically discharging region, it becomes electrically strongly charged toner Tb. This exemplary variation can provide the same effect as the first embodiment, and in addition, reduce the apparatus's cost.
The discharging member may have a shape other than a roller and a sheet. For example, the discharging member may be composed of a wire or a plurality of needles that generates corona discharge. The wire and secondary transfer roller 33 are disposed in parallel with a predetermined space therebetween. The plurality of needles are disposed in the direction of the length of the secondary transfer roller. The tip of each needle and the surface of secondary transfer roller 33 are spaced as predetermined. When direct-current voltage VN2 is applied to the wire or each needle, corona discharge occurs throughout the wire or at the tip of each needle, and negative ions are generated by corona discharge. Electrically weakly charged toner Ta on the surface of secondary transfer roller 33 is turned into electrically strongly charged toner Tb by the negative ions. This exemplary variation can also achieve the same effect as the first embodiment.
When large direct-current voltage VN3 identical in polarity to the toner is applied to secondary transfer roller 33, then, as shown in
The second embodiment can achieve the same effect as the first embodiment and in addition, prevent deposition of toner on the surface of second transfer roller 33. In addition, the toner is moved while sheet S is not inserted in nip NP (that is, for a period of time between toner images T2 and T3), and sheet S will never have the back surface smeared with the toner.
In
One sheet S1 is supplied to nip NP, as timed to coincide with toner image T1. Toner image T1 and sheet S1 are of the same size. While sheet S1 is inserted in nip NP, i.e., for a period of time of t1 to t2, control voltage VC1 is set to large positive voltage VP1 opposite in polarity to the toner. Thus, toner image T1 on the surface of intermediate transfer belt 30 is transferred to a surface of sheet S1.
While sheet S1 is not inserted in nip NP, i.e., for a period of time of t2 to t6, control voltage VC1 is set to small negative voltage VN1 identical in polarity to the toner. This suppresses adhesion of toner of patch images P1 and P2 or the like to the surface of secondary transfer roller 33. Note, however, that patch images P1 and P2 do come into contact with secondary transfer roller 33, and a small amount of toner adheres to the surface of secondary transfer roller 33. The toner adhering to the surface of secondary transfer roller 33 includes electrically weakly charged toner Ta (see
In response to the leading edges of patch images P1 and P2 having reached nip NP, control voltage VC2 is set to large direct-current voltage VN2 (for example, −2 kV to −3 kV) identical in polarity to the toner only for a predetermined period of time (of times t5-t6). More specifically, the trailing edges of patch images P1 and P2 reach nip NP at time t4, and thereafter when time LS arrives, control voltage VC2 falls from 0 V to direct-current voltage VN2, and thereafter when a predetermined period of time elapses, or when time t6 arrives, control voltage VC2 is raised from direct-current voltage VN2 to 0 V. Further, at time t6, control voltage VC1 is raised from direct-current voltage VN1 to 0 V.
When control voltage VC2 is set to direct-current voltage VN2, electric discharge 63 occurs on opposite sides of the nip between discharging member 34 and secondary transfer roller 33. When electrically weakly charged toner Ta adhering to the surface of secondary transfer roller 33 passes between discharging member 34 and secondary transfer roller 33, electrically weakly charged toner Ta is exposed to electric discharge 63 and becomes electrically strongly charged toner Tb negative in polarity (see
After a predetermined period of time elapses, or when time t7 arrives, control voltage VC1 falls from 0 V to large negative voltage VN3 identical in polarity to the toner. When control voltage VC1 is set to negative voltage VN3, electrically strongly charged toner Tb on the surface of secondary transfer roller 33 moves to the surface of intermediate transfer belt 30, and the toner on the surface of secondary transfer roller 33 is thus removed. The toner having moved to the surface of intermediate transfer belt 30 is removed by cleaning blade 42 located downstream, and discarded.
The third embodiment allows the toner on the surface of secondary transfer roller 33 to be sufficiently removed, and ensures that in subsequent printing, sheet S can be prevented from having a back surface smeared with toner. In addition, when printing is finished, the toner on secondary transfer roller 33 is removed, and a waiting time and hence impaired productivity can also be avoided.
Although embodiments of the present invention have been described and illustrated in detail, the disclosed embodiments are made for purposes of illustration and example only and not limitation. The scope of the present invention should be interpreted by terms of the appended claims.
Number | Date | Country | Kind |
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2018-050984 | Mar 2018 | JP | national |