The present disclosure relates to a fixing unit for fixing an image on a recording material and an image forming apparatus for forming an image on a recording material.
An example of a fixing unit adopting a heat-fixing system that is installed in a printer or a copying machine of an electrophotographic system is equipped with a heater having a heating resistor provided on a substrate formed of ceramics or the like, a fixing film that moves while being in contact with the heater, and a pressure roller arranged to oppose the heater with the fixing film interposed therebetween. A recording material that bears an unfixed toner image is heated while being nipped and conveyed at a nip portion, i.e., a fixing nip portion, formed between the fixing film and the pressure roller, by which the toner image borne on the recording material is heated and fixed to the recording material.
According to the fixing unit adopting the above-mentioned heat-fixing system, there was fear that image defects as described below may occur by using a recording material that has been left standing for a long time in a high temperature and high humidity environment, during which time the recording material absorbs moisture and electric resistance thereof has been reduced. If the recording material is nipped by the fixing nip portion while transfer of toner image is performed, an AC voltage applied to heat the heater is transmitted to a transfer nip portion through the recording material and superposed to a transfer voltage applied to a transfer member. Thereby, transfer current that flows from the transfer member to an image bearing member is fluctuated by waveform components of the AC voltage, so that the transfer property becomes uneven, and as a result, image defects caused by stripe-like density unevenness that occurs in a sub-scanning direction of the image, hereinafter referred to as AC-induced banding, may appear.
Japanese Patent Application Laid-Open Publication No. 2011-215538 discloses providing a detection circuit for detecting a current flowing to a transfer member, and if fluctuation of the current detected by the detection circuit during transfer of a toner image to a recording material is greater than a predetermined value, determining that AC-induced banding has occurred and controlling a transfer voltage being applied to the transfer member.
However, according to the method disclosed in the above document, the transfer voltage may be varied even in a case where the transfer current is fluctuated by causes other than the AC voltage derived from the fixing unit, and there was a risk that controlling of the transfer voltage may not lead to a reduction of image defects.
The present disclosure provides a fixing unit and an image forming apparatus capable of suppressing AC-induced banding without controlling of a transfer voltage.
According to one aspect of the disclosure, a fixing unit includes a film with a tubular shape, a nip forming unit including a heater and configured to be in sliding contact with an inner surface of the film, the heater including a substrate made of metal, an insulating layer formed on the substrate, and a heating element arranged on the insulating layer and configured to generate heat when a first AC voltage is applied from an AC power supply connected thereto, a pressing member opposed to the nip forming unit with the film interposed therebetween and configured to form a nip portion with the film, wherein a recording material is nipped and conveyed by the nip portion so that an image formed by toner on the recording material is heated and fixed to the recording material, and a voltage application circuit configured to apply a second AC voltage to the substrate with a waveform that takes a voltage value of an opposite polarity to the first AC voltage when the first AC voltage takes a peak value.
According to another aspect of the disclosure, a fixing unit includes a film with a tubular shape, a nip forming unit including a heater and configured to be in sliding contact with an inner surface of the film, the heater including a substrate made of metal, an insulating layer formed on the substrate, and a heating element arranged on the insulating layer and configured to generate heat when an AC voltage is applied from an AC power supply connected thereto, a pressing member opposed to the nip forming unit with the film interposed therebetween and configured to form a nip portion with the film, wherein a recording material is nipped and conveyed by the nip portion so that an image formed by toner on the recording material is heated and fixed to the recording material, and a voltage application circuit configured to apply a constant DC voltage with respect to a potential of a grounded-side of the AC power supply or a voltage equivalent to the potential of the grounded-side of the AC power supply to the substrate.
Further features of the present invention will become apparent from the following description of exemplary embodiments with reference to the attached drawings.
Exemplary embodiments according to the present disclosure will be described with reference to the drawings.
(1) Image Forming Apparatus
When a print command is received by the printer 100, a scanner unit 3 emits laser light L according to image information to a photosensitive member 1 serving as an image bearing member. The photosensitive member 1 charged to predetermined polarity by a charge roller 2 is scanned by laser light L, and an electrostatic latent image according to image information is thereby formed on a surface of the photosensitive member 1. Thereafter, toner is supplied to the photosensitive member 1 from a developing unit 4, and a toner image corresponding to the image information is formed on the photosensitive member 1. The toner image having reached a transfer portion, i.e., transfer nip portion, that has been formed between the photosensitive member 1 and a transfer roller 5 serving as a transfer unit along with the rotation of the photosensitive member 1 in the direction of arrow R1 is transferred onto a recording material P fed from a cassette 6 by a pickup roller 7. The surface of the photosensitive member 1 having passed the transfer nip portion is cleaned by a cleaner 8. The recording material P to which toner image t (
Thereafter, the recording material P is discharged onto a tray 11 by a sheet discharge roller 10. Various types of sheets of different sizes and materials may be used as the recording material P, such as paper including normal paper and thick paper, plastic films, cloth, coated paper and other sheet materials subjected to surface treatment, and sheets of special shapes such as envelopes and index paper. The present example is illustrated based on a system where toner image is directly transferred from the photosensitive member 1 to the recording material P, but it is also possible to apply the technique illustrated hereafter to an image forming apparatus that adopts a system where toner image formed on the photosensitive member is transferred to the recording material via an intermediate transfer member such as an intermediate transfer belt.
(2) Fixing Unit
The fixing unit 9 will now be described. The fixing unit 9 is a tensionless-type film heating system. That is, the fixing unit 9 uses a fixing film in the form of an endless belt, or a round tubular shape, having flexibility as a heat resistant film, and adopts a configuration where at least a part of the circumference of the fixing film is constantly tensionless and the fixing film rotates by rotational driving force of the pressing member.
Hereafter, the fixing unit 9 of the film heating system according to the present embodiment will be described in detail.
The fixing unit 9 according to the present embodiment includes, as illustrated in
The heater holder 21 is a molded component formed of heat-resistant resin such as PPS (polyphenylene sulfide) or liquid crystal polymer. The heater 22 includes a substrate mainly composed of a pure metal or an alloy and having an elongated plate shape, i.e., metal substrate, a resistance heating element, i.e., heating element, that generates heat by electric power conduction, an insulating layer for insulating the resistance heating element and the substrate, and a glass coat layer for protecting the heating element. The details of the heater 22 will be described later.
A thermistor 25 serving as a temperature detecting element is abutted against the heater 22 at an opposite side, that is, upper side in the drawing, from an abutting surface against the fixing film 23. By controlling the electric power conduction to the heating element in accordance with the detection temperature of the thermistor 25, the temperature of the fixing nip portion Nf is maintained at a set temperature suitable for fixing the image.
The thickness of the fixing film 23 should preferably be between 20 μm and 100 μm to ensure good thermal conductivity. A single-layer film formed of a material such as PTFE (polytetrafluoroethylene), PFA (tetrafluoroethylene-perfluoro alkyl vinyl ether copolymer) or PPS is suitable as the fixing film 23. Further, a composite layer film in which a surface of a base layer formed of a material such as PI (polyimide), PAI (polyamide imide), PEEK (polyether ether ketone) or PES (polyethersulfone) is coated with a material such as PTFE, PFA or FEP (tetrafluoroethylene-hexafluoropropylene copolymer) as a release layer, i.e., surface layer, is also suitable as the fixing film 23. Even further, it is also suitable to use a pure metal or an alloy having high thermal conductivity as the base layer, and to apply the aforementioned coating treatment and coating of a fluororesin tube to the release layer. Examples of the pure metal are Al, Ni, Cu and Zn, and examples of the alloy are a stainless steel and alloys of Al, Ni, Cu and Zn.
According to the present embodiment, PI having a thickness of 60 μm was used as the base layer of the fixing film 23, and coating of PFA having a thickness of 12 μm was provided as the release layer, considering both wear of the release layer by passing of sheets and thermal conductivity.
The pressure roller 30 serving as a pressing member, i.e., pressurizing rotary member, includes a core metal 30a formed of a material such as iron or aluminum, an elastic layer 30b formed of a material such as silicone rubber, and a release layer 30c formed of a material such as PFA (
The configuration of the fixing unit will now be described with reference to the cross-sectional view of
Next, the present embodiment is described by referring to the perspective view of
Both end portions of the reinforcement member 24 in the longitudinal direction are projected portions that protrude from both ends of the fixing film 23, having flange members 26 and 26 respectively fit thereto. The fixing film 23, the heater 22, the heater holder 21, the reinforcement member 24 and the flange members 26 and 26 are assembled together as the film assembly 20.
A power feed terminal of the heater 22 is also protruded from one side in the longitudinal direction with respect to the fixing film 23, and a power feed connector 27 is fit to the power feed terminal. The power feed connector 27 is in contact with an electrode portion of the heater 22 with a certain contact pressure and constitutes a power supply path for supplying power fed from a commercial power supply to the heater 22.
A heater clip 28 is attached to the other side, that is, the side opposite to the power feed terminal, of the heater 22 in the longitudinal direction. The heater clip 28 is a metal plate that is bent in a U shape and has a spring property that enables the end portion of the heater 22 to be retained on the heater holder 21.
Next, the present embodiment is described with reference to the front view of
Further, the length of the pressure roller 30 in the longitudinal direction is set approximately 10 mm shorter than the fixing film 23. This arrangement is adopted to prevent grease from leaking from ends of the fixing film 23 and adhering to the pressure roller 30, causing the pressure roller 30 to lose its gripping force on the recording material and slip.
The film assembly 20 is arranged to oppose to the pressure roller 30 and supported on a top-side casing 41 of the fixing unit 9 in a state where movement in the longitudinal direction, i.e., right-left directions in the drawing, is restricted and movement in the vertical direction is enabled. A pressurizing spring 45 serving as a pressurizing member is attached in a compressed manner to the top-side casing 41. The pressing force of the pressurizing spring 45 is received by the projected portion of the reinforcement member 24, and by having the reinforcement member 24 press against the pressure roller 30, the whole film assembly 20 is pressed against the pressure roller 30.
A bearing member 31 is provided to bear the core metal of the pressure roller 30 (refer also to
The bottom-side casing 43 and the top-side casing 41 constitute a casing, i.e., frame member, of the fixing unit 9 together with frame side panels 42 and 42 that are provided on both sides in the longitudinal direction of the film assembly 20 and extend upward and downward.
(3) Heater
Next, materials constituting the heater 22 according to the present embodiment and a method for manufacturing the same will be described with reference to
Materials such as stainless steel, nickel, copper or aluminum, or an alloy mainly composed of these metals are suitably used as the material for the substrate 22a. Among these materials, stainless steel is most preferable from the viewpoint of strength, heat resistance and corrosion. The type of stainless steel is not specifically limited, and any type can be selected as required considering necessary mechanical strength, linear expansion coefficient corresponding to the shape of the insulating layer and the heating element described in the next section, availability of the plate material in the market, and so on.
As an example, a martensitic- or ferritic-type chromium-containing stainless steel has a relatively low linear expansion coefficient among stainless steels and easily applied to forming an insulating layer and a heating element, so that it is suitable.
The thickness of the substrate 22a can be determined considering strength, heat capacity and radiation performance. A thin substrate 22a is advantageous for realizing a quick-start performance, that is, short time from starting of electric power conduction to reaching a target temperature of the heater 22, since it has a small heat capacity, but if it is too thin, a problem such as distortion of the substrate during sintering (firing) treatment of the heating resistor tends to occur. In contrast, a thick substrate 22a is advantageous from the viewpoint of preventing distortion of the heating resistor during thermoforming, but excessive thickness increases the heat capacity and is disadvantageous in realizing a quick start. Preferable thickness of the substrate 22a, considering the balance of mass productivity, cost and performance, is between 0.3 mm and 2.0 mm.
The material of the insulating layers 22b and 22e is not specifically limited, but it is necessary to select an insulating material having heat resistance in view of the actual temperature during use. The material of the insulating layers 22b and 22e is preferably glass or PI (polyimide) from the viewpoint of heat resistance, and in the case of glass, the actual powder material to be used should be selected within a range not deteriorating the characteristics of the present embodiment. A heat-conductive filler having an insulating property may be mixed as needed. There is no problem in using the same material or different materials for the insulating layers 22b and 22e. Similarly, the thickness may be the same within the insulating layers 22b and 22e or varied as needed.
In general, the heater 22 to be used in the image forming apparatus should preferably have a dielectric voltage of approximately 1.5 kV. Therefore, the thickness of the insulating layer 22b should be determined according to the material to realize a dielectric voltage performance of 1.5 kV between the heating element 22c and the substrate 22a.
The method for forming the insulating layers 22b and 22e is not specifically limited, but as an example, the insulating layers 22b and 22e can be formed smoothly by adopting screen printing. When forming an insulating layer of glass or PI (polyimide) on the substrate 22a, it is necessary to adjust the linear expansion coefficients of the substrate and the insulating layer material as required so that cracking and peeling do not occur in the insulating layer by the difference between linear expansion coefficients of the materials.
The heating element 22c is formed by printing a heating resistor paste having mixed (A) conductive component, (B) glass component and (C) organic binder component onto the insulating layer 22b, and then sintering the paste. When the heating resistor paste is sintered, the (C) organic binder component is burnt out and only components (A) and (B) are left, so that the heating element 22c containing the conductive component and the glass component is formed.
In the embodiment, materials such as silver-palladium (Ag—Pd) and ruthenium oxide (RuO2) are used alone or in combination as the conductive component (A), and a sheet resistance of 0.1[Ω/□] to 100 [KΩ/□] is suitable. Materials other than those mentioned above in (A) to (C) can also be contained as long as the amount is subtle enough so as not to deteriorate the characteristics of the present embodiment.
A power supplying electrode 22f and a conductive pattern 22g illustrated in
Note that, it is necessary to select a material that softens and melts at a temperature lower than a melting point of the substrate 22a and a material that has sufficient heat resistance in consideration of the temperature during actual use as the aforementioned heating resistor paste and the paste for forming the power supplying electrode and conductive pattern.
As illustrated in
In the present embodiment, a ferritic stainless-steel substrate (18 Cr stainless-steel) having a width (i.e., dimension in the short direction) of 10 mm, a length (i.e., dimension in the longitudinal direction) of 300 mm, and a thickness (i.e., dimension in the thickness direction) of 0.5 mm was prepared as the substrate 22a.
Next, the glass paste for forming the insulating layer was applied on the aforementioned stainless-steel substrate by screen printing, and then dried at 180° C. and sintered at 850° C. to form the insulating layers 22b and 22e. The thickness of the insulating layers 22b and 22e after sintering were both 60 μm.
Thereafter, a heating resistor paste and a paste for forming a power supply electrode and a conductive pattern were prepared. The heating resistor paste contains silver-palladium (Ag—Pd) as the conductive component, with a glass component and an organic binder component mixed thereto. The paste for forming the power supply electrode and the conductive pattern contains silver as the conductive component, with a glass component and an organic binder component mixed thereto. The respective pastes were applied to the stainless-steel substrate by screen printing, and then dried at 180° C. and sintered at 850° C. to form the heating element 22c, the power supplying electrode 22f and the conductive pattern 22g. After sintering, the thickness of the heating element 22c was 15 μm, the length was 220 mm and the width was 1.1 mm.
Next, the glass paste for the cover layer was prepared, and the glass paste for the cover layer was applied on the heating element 22c and the conductive pattern 22g by screen printing, and then dried at 180° C. and sintered at 850° C. to form the cover layer 22d. The thickness of the cover layer 22d after sintering was 60 μm.
(4) Mechanism of AC-Induced Banging
Next, an image defect, i.e., AC-induced banding, that occurs by the AC voltage of a commercial power supply 65 being superposed to a transfer voltage Vt at the transfer nip portion through a recording material P having absorbed moisture and having a low electric resistance when forming an image on the recording material P will be described with reference to
AC-induced banding occurs when the recording material P is nipped by the fixing nip portion Nf in a state where the recording material P having absorbed moisture is being subjected to transfer of toner image from the photosensitive member 1 at the transfer nip portion Nt. In this state, AC voltage (first AC voltage) is applied to the heater 22 from the commercial power supply 65, and waveform control of AC voltage is performed by a triac 68. The recording material P nipped by the fixing nip portion Nf is in contact with a fixing film 23, and the fixing film 23 is in contact with the heater 22 at the fixing nip portion Nf.
As illustrated in
Time T1 of
As illustrated in
With reference to
Meanwhile, if the power plug is inserted in the direction shown in
If a switching element such as the triac 68 for switching the feeder circuit of the heating element 22c between an open state and a closed state is provided, there is a difference in the tendency of occurrence of AC-induced banding based on the position of the heating element 22c on the feeder circuit and the relationship of connection with the commercial power supply 65. According to the configuration of
(5) Driving Circuit of Heater
The present embodiment adopts a configuration where AC voltage (second AC voltage) is applied to a substrate 22a made of metal of the heater 22 as a method for reducing the above-mentioned AC-induced banding. That is, as illustrated in
The driving circuit of the heater 22 according to the present embodiment will be described with reference to
In other words, the inverting amplifier 105 having an operational amplifier constitutes a voltage application circuit that generates an AC voltage (Vb) having the same frequency as the AC voltage (Vac) supplied to the heating element 22c but with the phase inverted and applies the same to the substrate 22a of the heater 22. That is, at a point of time where the AC voltage (Vac) of the commercial power supply 65 applied to the heating element 22c takes a peak value, the AC voltage (Vb) applied to the substrate 22a takes a voltage value having an opposite polarity as Vac. The inverting amplifier 105 functions as a voltage application circuit according to the present embodiment that applies the AC voltage (Vb) to the substrate 22a of the heater 22 through the bundle wire 29 and the heater clip 28.
As illustrated in
According to the circuit structure of the present embodiment, even in a case where the power plug is inserted in the direction of
The inverting amplifier 105 using an operational amplifier was used according to the present embodiment as the voltage application circuit for applying the voltage having an inverted phase as the commercial power supply 65 to the substrate 22a, but the AC voltage having an inverted phase as the commercial power supply 65 can also be generated using other known circuits.
A configuration where the driving circuit of the heater 22 is directly connected to the commercial power supply 65 has been illustrated in the present embodiment, but the present technique is also applicable to a case where the driving circuit is connected to another AC power supply.
A fixing unit according to a second embodiment will be described with reference to
A main difference from the first embodiment is that a frequency of voltage applied to the substrate 22a differs from a frequency of the commercial power supply 65.
A voltage application circuit for applying voltage, i.e., applying potential, to the substrate 22a of the present embodiment will be described with reference to
The microcomputer 204 launches a triangular wave activation signal V24 (
As described, triangular waves V25 are started to be applied to the substrate 22a after time t2 has elapsed from the rising of voltage V1 of the commercial power supply. The triangular wave generation unit 220 that generates triangular waves based on a synchronization signal (V22) of the microcomputer 204 and that applies the same to the substrate 22a of the heater 22 functions as the voltage application circuit of the present embodiment.
By setting the waveform to be superposed, which in this case is the triangular waves, to have a frequency of an odd number multiple of the reference frequency (of the commercial power supply) and adjusting the time t2, a maximum amplitude (i.e., peak-to-peak value) of the AC waveform components Vf as an associated wave can be suppressed. In other words, the frequency and phase of V25 are set so that the AC voltage (V25) applied to the substrate 22a takes a voltage value having an opposite polarity as V1 at each point of time when the AC voltage (V1) supplied from the commercial power supply 65 takes a peak value. Thereby, it becomes possible to reduce actualization of AC-induced banding.
According to the present embodiment, triangular waves that can be generated relatively easily are adopted as the AC voltage, and the frequency of the triangular peaks are set to three times the frequency of the commercial power supply, but other waveforms and frequencies can be adopted. The waveform of the AC voltage applied to the substrate 22a of the heater 22 can be directly generated from the commercial power supply using a converter circuit and an inverter circuit, for example.
A fixing unit according to a third embodiment will be described with reference to
A main difference from the first embodiment is that a voltage applied to the substrate 22a is a voltage V2 of a first end (terminal) of the commercial power supply 65.
The flow of voltage V2 being applied to the substrate 22a will be described with reference to
The voltage V1 (
In a state where the voltage V5 is set to high, current is flown through a transistor 305 to a relay 307 while turning on a transistor 306, so that the grounded side of the commercial power supply 65 and the substrate 22a are communicated. As described, if sine waves are detected in the voltage V1, 0 V is continuously supplied to the substrate 22a. In other words, once power is entered to the heater 22 in a state where the substrate 22a is connected to a grounded side circuit, a potential equivalent to grounded-side potential of the commercial power supply 65 is constantly applied to the substrate 22a.
A partial circuit that connects the substrate 22a and a feeder circuit through which electric power is conducted from the commercial power supply 65 to the heating element 22c, i.e., a path composed of the bundle wire 29 and the heater clip 28 of
Now, taking a case where the triac 68 is turned on and off by a cycle equivalent to a cycle of the voltage V1 of the commercial power supply 65, the voltage being applied to the recording material P at the fixing nip portion Nf will be described with reference to the graphs of
A case where the voltage V1 is the non-grounded side and the voltage V2 is the grounded side is considered, so that the graphs of V1, V2, V7 and the heater current I are as illustrated in
By comparing voltages P1, P2 and P3 with voltages P11, P21 and P31 of
Now, a behavior of a case illustrated by a dashed line of
If the triac 68 is turned on and off by a cycle equivalent to the cycle of the voltage V1 of the commercial power supply 65, the graphs of V1, V2, V7 and the heater current I will be as illustrated in
In other words, the breaking circuit extending from the comparator circuit 308 to the relay 307 functions as a breaker for cutting off (floating) the substrate 22a and the contact 29a by the relay 307 in a state where the heating element 22c is connected to the grounded side of the commercial power supply 65 with respect to the triac 68. Meanwhile, in a state where the heating element 22c is connected to the non-grounded side of the commercial power supply 65 with respect to the triac 68, as mentioned above, the relay 307 will be in a constantly on state, i.e., conducting state, and the substrate 22a is maintained at grounded-side potential.
The voltage applied to the substrate 22a is not necessarily a grounded-side potential of the commercial power supply 65, and it may be the grounded-side potential itself or a DC potential, i.e., DC voltage, with respect to the grounded-side potential. The configuration for applying voltage is not limited to the circuit structure of the present embodiment.
The effects of the first, second and third embodiments will be described in comparison with a comparative example. A configuration where no voltage is applied to the substrate 22a is taken as a comparative example. In order to verify the effects of the first, second and third embodiments, presence of occurrence of AC-induced banding was confirmed using a recording material P having been left standing for a long time in a high temperature and high humidity environment. An image coverage pattern for evaluating AC-induced banding was a solid black pattern in which toner is applied to an entire surface of an effective image area, and a long-left paper that has been left standing for approximately one week after being unsealed was used as the recording material P. Since the test was performed under a high temperature and high humidity environment with a temperature of 32.5° C. and a humidity of 80%, moisture content of the recording material P was approximately 8%. Xerox Vitality (75 g/m2, LTR) was used as the recording material P. A 240-V 50-Hz power supply was used as the commercial power supply 65 for evaluation. A voltage of 760 V was used as the transfer voltage Vt.
As illustrated in Table 1, in the case of long-left paper, an AC-induced banding image in correspondence with a 50-Hz cycle of power supply frequency has occurred from the position where the recording material P has entered the fixing nip portion Nf, i.e., 40 mm from a leading edge of the paper, to the rear end of the image. This is because the voltage Vac, which is 240 V, of the commercial power supply 65 that drives the heater 22 having been attenuated to approximately 60 V after passing through the heater 22, the fixing film 23 and the recording material P has been superposed to the voltage of the transfer nip portion Nt. As a result, the current flowing from the transfer roller, which is correlated with transfer property, to the drum is fluctuated as illustrated in
In the configuration of the first embodiment, the AC waveform component Vf derived from the fixing unit 9 superposed to the transfer voltage Vt through the recording material P was reduced from 60 V to 30 V by applying to the substrate 22a a voltage having inverted the phase of the voltage Vac of the commercial power supply 65. Therefore, a state was realized where voltage having an amplitude Vpp of approximately 30 V was superposed to the transfer voltage Vt of 760 V, by which the transfer nip portion voltage Vnt did not fall below the transfer voltage 720 V causing transfer failure, so that AC-induced banding did not occur.
In the configuration of the second embodiment, the AC waveform component Vf derived from the fixing unit 9 superposed to the transfer voltage Vt through the recording material P was reduced from 60 V to 30 V by adopting an AC waveform having a frequency that is three times the frequency of the commercial power supply 65 using triangular waves that are relatively easy to generate. Therefore, a state was realized where voltage having an amplitude Vpp of approximately 30 V was superposed to the transfer voltage Vt of 760 V, by which the transfer nip portion voltage Vnt did not fall below the transfer voltage 720 V causing transfer failure, so that AC-induced banding did not occur.
In the configuration of the third embodiment, the AC waveform component Vf derived from the fixing unit 9 superposed to the transfer voltage Vt through the recording material P was reduced from 60 V to 30 V by applying 0 V to the substrate 22a so as to suppress the voltage transmitted to the recording material P. Therefore, a state was realized where voltage having an amplitude Vpp of approximately 30 V was superposed to the transfer voltage Vt of 760 V, by which the transfer nip portion voltage Vnt did not fall below the transfer voltage 720 V causing transfer failure, so that AC-induced banding did not occur.
As described above, according to the first, second and third embodiments, the AC waveform component Vf of the voltage applied to the recording material P at the fixing nip portion can be reduced by applying to the substrate 22a a voltage having a waveform that differs from the voltage Vac of the commercial power supply 65 applied to the heating element 22c. According to the present embodiments, the occurrence of AC-induced banding can be suppressed since the AC waveform component Vf derived from the fixing unit 9 being superposed to the transfer voltage Vt through the recording material P can be reduced.
According to the embodiments described above, the heater 22 is directly in contact with the inner surface of the film in the fixing unit. However, a sheet-like member having a high thermal conductivity such as a sheet-like member formed of ferrous alloy or aluminum can be arranged between the heater and the inner surface of the film. In other words, a nip forming unit adopting a configuration where the heater heats the film through a sheet-like member can also be adopted.
While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. The scope of the following claims is to be accorded the broadest interpretation so as to encompass all such modifications and equivalent structures and functions.
This application claims the benefit of Japanese Patent Application No. 2020-026805, filed on Feb. 20, 2020, which is hereby incorporated by reference herein in its entirety.
Number | Date | Country | Kind |
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JP2020-026805 | Feb 2020 | JP | national |
Number | Name | Date | Kind |
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20100310267 | Shimura | Dec 2010 | A1 |
20130195483 | Shimizu | Aug 2013 | A1 |
20180275592 | Shimazoe | Sep 2018 | A1 |
Number | Date | Country |
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2002049259 | Feb 2002 | JP |
2011215538 | Oct 2011 | JP |
2016024435 | Feb 2016 | JP |
Entry |
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Co-pending U.S. Appl. No. 17/174,514, filed Feb. 12, 2021. |
Number | Date | Country | |
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20210263461 A1 | Aug 2021 | US |