The present invention relates to a heating apparatus used, for example, for image forming apparatuses, such as printers and copiers, and a heating rotating member used for the heating apparatus.
As a heating apparatus used for conventional image forming apparatuses, such as printers and copiers, for example, the heating apparatus described in Japanese Patent Application Laid-open No. 2013-97315 is known.
This heating apparatus has a heating rotating member, a power feeding member for feeding power to the heating rotating member, and a pressurizing member that comes into pressure contact with the heating rotating member to form a nip portion. By feeding power to the heating rotating member to generate Joule heat, the heating apparatus allows high-speed start-up and saves energy. The heating rotating member has a heat generating layer coated with an insulating layer. The heating rotating member generates heat by feeding power directly to the heat generating layer, enabling a reduction in warm-up time.
In the conventional heating rotating member, however, the insulating layer may be damaged by being rubbed by foreign matter entering the image forming apparatus or by recording materials, and the damage may even reach the heat generating layer. Moreover, for example, in connection with a jam eliminating process forcibly executed by a user, the heat generating layer may be damaged by a cutter. The heat generating layer damaged in this manner may locally increase a current density around ends of the damaged portion of the heat generating layer, leading to abnormal heat generation in the corresponding portions.
An object of the present invention is to provide a tubular film used for a fixing apparatus, the tubular film including a heat generating layer, and a first conductive layer and a second conductive layer provided respectively at one end and another end of the film in a longitudinal direction of the film, so as to contact the heat generating layer. The first conductive layer and the second conductive layer both have a lower volume resistivity than that of the heat generating layer. In addition, the tubular film includes a low-resistance layer formed in an area of the heat generating layer between the first conductive layer and the second conductive layer in the longitudinal direction so as not to contact the first conductive layer and the second conductive layer. The low-resistance layer has a lower volume resistivity than that of the heat generating layer and extends in a circumferential direction of the heat generating layer.
Another object of the present invention is to provide a tubular film used for a fixing apparatus, the tubular film including a heat generating layer, and a plurality of low-resistance layers formed in an area of the heat generating layer at least except for one end and another end of the film in a longitudinal direction of the film. The low-resistance layers are formed at intervals in the longitudinal direction so as not to contact one another, and the low-resistance layers have a lower volume resistivity than that of the heat generating layer and extend in a circumferential direction of the heat generating layer.
Yet another object of the present invention is to provide a fixing apparatus that fixes an image to a recording material, the fixing apparatus including a heating rotating member having a heat generating layer, and a first conductive layer and a second conductive layer provided respectively at one end and another end of the heating rotating member in a longitudinal direction of the heating rotating member so as to contact the heat generating layer. The first conductive layer and the second conductive layer both have a lower volume resistivity than that of the heat generating layer. Power feeding members contact the first conductive layer and the second conductive layer, respectively. The heat generating layer generates heat by a current flowing between the power feeding members and the heat generating layer, and the image is fixed to the recording material by heat from the heating rotating member. In addition, the heating rotating member has a low-resistance layer formed in an area of the heat generating layer between the first conductive layer and the second conductive layer in the longitudinal direction so as not to contact the first conductive layer and the second conductive layer, and the low-resistance layer has a lower volume resistivity than that of the heat generating layer and extends in a circumferential direction of the heat generating layer.
Still another object of the present invention is to provide a fixing apparatus that fixes an image to a recording material, the fixing apparatus including a heating rotating member having a heat generating layer, and power feeding members that contact one end and another end of the heating rotating member in a longitudinal direction of the heating rotating member. The heat generating layer generates heat by a current flowing between the power feeding members and the heat generating layer. A pressurizing member forms a nip portion in cooperation with the heating rotating member. In the nip portion, the recording material on which the image is formed is heated while being conveyed to fix the image to the recording material. In addition, the heating rotating member has a plurality of low-resistance layers formed in a conveying area for the recording material in the heat generating layer at intervals in the longitudinal direction so as not to contact one another, each of the low-resistance layers having a lower volume resistivity than that of the heat generating layer and extending in a circumferential direction of the heat generating layer.
Further features of the present invention will become apparent from the following description of exemplary embodiments with reference to the attached drawings.
The present invention will be described below in detail based on illustrated embodiments.
In the description below, a longitudinal direction represents a generatrix direction of a cylindrical shape of a heating rotating member surface. A circumferential direction represents a rotating direction of the heating rotating member surface corresponding to a circumferential direction of the cylindrical shape of the heating rotating member surface. A thickness direction represents a radial direction of the cylindrical shape of the heating rotating member surface.
First, a configuration of the fixing film 1 serving as the heating rotating member will be described. Then, a fixing apparatus using the fixing film 1 will be described.
Description of the Fixing Film
A configuration of a fixing film 1 in Embodiment 1 of the present invention will be described using
As depicted in
The heat generating layer 1a is a base layer that provides the fixing film 1 with mechanical properties, such as torsional strength and smoothness. The heat generating layer 1a is formed of a resin, such as polyimide (PI), polyamideimide (PAI), or polyether ether keton (PEEK). A conductive filler that is carbon, metal, etc. is dispersed in the heat generating layer 1a such that an alternating current is applied through the conductive layers 1b to adjust electric resistance so as to allow heat generation.
For example, the heat generating layer 1a used is a polyimide film that has an outside diameter of φ18, a longitudinal length of 240 mm, and a thickness of 60 μm, and in which carbon is dispersed as the conductive filler. The heat generating layer 1a has a volume resistivity set to approximately 0.03 Ω·cm.
The conductive layers 1b are provided over a predetermined width, for example, within the range of approximately 10 mm, from the respective opposite ends of the fixing film 1 in the longitudinal direction in order to supply power to the heat generating layer 1a through an inner surface of the fixing film 1. In the present embodiment, a silver paste is formed all over a surface of the heat generating layer 1a in the circumferential direction thereof as the conductive layer 1b for power feeding. In a specific example, the conductive layers 1b are formed of a silver paste with a volume resistivity of 4×10−5 Ω·cm. As the silver paste, silver particulates are dispersed in a polyimide resin using a solvent and then are fired. When the conductive layers 1b are formed on the heat generating layer 1a, the value of resistance between the conductive layers 1b at the opposite ends of the heat generating layer 1a in the longitudinal direction is set to, for example, approximately 19.3Ω.
An elastic layer 1c is formed of silicone rubber that has a predetermined thickness and in which a thermally conductive filler is dispersed. A release layer 1d is subjected to a coating treatment with a fluorine resin, for example, PFA (tetrafluoroethylene perfluoroalkylvinylether copolymer) so as to be set to have a layer thickness of approximately 15 μm. The elastic layer 1c and the release layer 1d are electrically insulated.
Furthermore, the present embodiment is characterized in that, besides the conductive layers 1b provided at the longitudinal ends for power feeding, a large number of endless, low-resistance layers 1e, each extending linearly in the circumferential direction, are formed in the longitudinal direction in order to form an equipotential surface. That is, each of the linear low-resistance layers 1e is continuous in the circumferential direction and is shaped like an independent ring. In the present embodiment, the low-resistance layers 1e, used to form the equipotential surface, are formed of a silver paste with a volume resistivity of 4×10−5 Ω·cm that is the same as the silver paste of which the conductive layers 1b are formed. A ratio of the volume resistance value of the low-resistance layers 1e to the volume resistance value of the heat generating layer 1a is preferably within the range from 1/1000 to 1/100. Desirably, the low-resistance layers 1e are formed of a flexible material and have a thickness of 100 μm or less so as not to prevent the heat generating layer 1a from being deformed. The effects of the present example can be produced with the width of each low-resistance layer 1e set to any value, so long as the width is appropriate to achieve conductivity. The width, however, is desirably 5 μm or more in view of pattern chipping and stability of a line width. In the present embodiment, as depicted in
Since a current passes through the low-resistance layers 1e extending in the circumferential direction in an endless manner, areas in which the respective low-resistance layers 1e are formed each generate a smaller amount of heat than each area of the heat generating layer 1a between adjacent low-resistance layers 1e with the low-resistance layer 1e not being formed therein. Consequently, an excessively large width of the low-resistance layer 1e is likely to lead to nonuniform temperatures on the surface of the fixing film 1. Thus, each low-resistance layer 1e is desirably 0.1 mm or more and 5 mm or less in width. Furthermore, the interval between the low-resistance layers 1e is desirably smaller than a circumferential length of the heat generating layer 1a (in the present embodiment, 57 mm). Moreover, a smaller interval between the low-resistance layers 1e allows the effects of the present embodiment to be more easily exerted but makes normal heat generating areas smaller. This results in a higher likelihood of a fluctuation in resistance caused by a variation in coating of the low-resistance layers 1e and joining of the adjacent low-resistance layers 1e. For example, when the adjacent low-resistance layers 1e are partly joined together, a reduced current flows through the heat generating layer 1a between these adjacent low-resistance layers 1e. Then, no heat is generated in this area, resulting in uneven heat generation. To ensure the above-described balance, the specific dimension of the interval between the low-resistance layers 1e is preferably set to 0.2 mm or more.
In the present embodiment, if the heat generating layer 1a has an actual resistance value of 18.0Ω at the opposite ends thereof in the longitudinal direction when the conductive layers 1b and the low-resistance layers 1e are formed on the heat generating layer 1a, the heat generating layer 1a has an actual resistance value of 19.3Ω at the opposite ends thereof in the longitudinal direction when only the conductive layers 1b are formed on the heat generating layer 1a. Formation of the low-resistance layers 1e reduces the total resistance of the fixing film 1 by 1.3Ω.
Furthermore, in the present embodiment, the conductive layers 1b for power feeding and the low-resistance layers 1e for equipotential-surface formation are provided on the same surface of the fixing film 1. The conductive layers 1b for power feeding and the low-resistance layers 1e for equipotential-surface formation may, however, be provided on different surfaces. For example, the conductive layers 1b may be provided on an inner surface of the fixing film 1, whereas the low-resistance layers 1e may be provided on an outer surface of the fixing film 1. Additionally, in the present embodiment, the low-resistance layers 1e are formed by printing the silver paste. The low-resistance layers 1e may be formed, however, by any other means, such as metal plating or sputtering.
Description of the Fixing Apparatus
Now, a configuration of a fixing apparatus that is a heating apparatus in Embodiment 1 of the present invention will be described using
The fixing apparatus is configured to heat and fix a toner image T formed on a recording material P using a general electrophotographic image forming method. That is, the fixing apparatus includes a cylindrical fixing film 1 serving as a heating rotating member, a film guide 2 that holds an inner peripheral surface of the fixing film 1, and a pressurizing roller 4 that forms a nip N between the pressurizing roller 4 and the film guide 2 via the fixing film 1. Then, the recording material P bearing the toner image T is conveyed from a left side in
The film guide 2 is formed of a heat resistant resin, such as a liquid crystal polymer, PPS, or PEEK, and is engaged, at opposite ends of the film guide 2 in the longitudinal direction, with a fixing stay 5 held by an apparatus frame. A pressurizing spring (not depicted in the drawings), serving as pressurizing means, pressurizes the fixing stay 5 at the opposite ends thereof in the longitudinal direction to pressurize the film guide 2 toward the pressurizing roller 4. In order to transmit, in the longitudinal direction of the film guide 2, the pressure received at the opposite ends of the fixing stay 5 in the longitudinal direction evenly, the fixing stay 5 has a high rigidity increased by forming the fixing stay 5 using a rigid material, such as iron, stainless steel, or a zinc chromate coat steel plate, such that the fixing stay 5 has a U-shaped section. Consequently, with possible deflection of the film guide 2 suppressed, the fixing nip N is formed that has a uniform predetermined width in the longitudinal direction of the pressurizing roller 4. Furthermore, a temperature sensing element 6 is installed on the film guide 2 and is in abutting contact with an inner surface of the fixing film 1. Conduction of a current through the fixing film 1 is controlled according to a temperature detected by the temperature sensing element 6.
The low-resistance layers 1e of the fixing film 1 are desirably provided in a paper passing area for the recording material P that has at least the minimum width at which the recording material P can pass through the paper passing area.
In the present embodiment, a liquid crystal polymer is used as a material for the film guide 2, and a zinc chromate coat steel plate is used as a material for the fixing stay 5. A pressurizing force applied to the pressurizing roller 4 is 160 N, and, at this time, the fixing nip N is formed to be approximately 6 mm in size.
The pressurizing roller 4 includes a cored bar 4a formed of a material such as iron or aluminum, an elastic layer 4b formed of a material such as silicone rubber, and a release layer 4c formed of a material such as PFA. The pressurizing roller 4 preferably has a hardness of approximately 40° to 70° under a 1-kgf load, as measured using an ASKER-C durometer, so as to achieve appropriate durability and an appropriate fixing nip N width for satisfactory fixability.
Specifically, a silicone rubber layer is formed on the iron cored bar 4a of φ11 to a thickness of 3.5 mm as the elastic layer 4b, and then is coated with an insulating PFA tube with a thickness of 40 μm as the release layer 4c. The pressurizing roller 4 has a surface hardness of 56° and an outside diameter of φ18. The elastic layer 4b and the release layer 4c have a longitudinal length of 240 mm.
Furthermore, power feeding members 3a, 3b are connected to an AC power supply 50 through AC cables 7 and are disposed inside the fixing nip N at the opposite ends thereof so as to be pressed toward and against the pressurizing roller 4. In the present embodiment, as the power feeding members 3a, 3b, carbon brushes are used that are formed of metal graphite containing approximately 60% of copper. An AC voltage from the AC power supply 50 is applied to the carbon brushes via the AC cables 7 to achieve power feeding to the ends of the heat generating layer 1a of the fixing film 1. The power feeding members 3a, 3b are pressed against the rubber of the pressurizing roller 4 over a width of 6 mm in a conveying direction so as to protrude into the fixing nip N to a position 6 mm away from each of the opposite ends of the fixing nip N.
In the present embodiment, the conductive layers 1b are provided at the respective opposite ends of the heat generating layer 1a of the fixing film 1. This allows suppression of nonuniform heating in the circumferential direction of the fixing film 1. This is because the resistance value of the heat generating layer 1a of the fixing film 1 is much smaller in a thickness direction than in the longitudinal direction, causing a current from the power feeding members 3a, 3b to pass through the heat generating layer 1a in the thickness direction and then to uniformly flow all along the circumference of the heat generating layer 1a via the conductive layers 1b. The heat generating layer 1a has a resistance value of several mΩ in the thickness direction, and thus, the heat generation in this direction is not important. Furthermore, power is fed not from an outer peripheral side of the fixing film 1 around which the conductive layers 1b are formed, but from an inner peripheral side of the fixing film 1, preventing the conductive layers 1b from being scraped by the power feeding members 3a, 3b. Thus, stable power feeding can be achieved through durability.
A turning force from a driving mechanism portion (not depicted in the drawings) is transmitted to a driving gear G for the pressurizing roller 4, and then, the pressurizing roller 4 is rotationally driven at a predetermined speed in a counterclockwise direction as depicted in
Rotation of the pressurizing roller 4 rotates the fixing film 1 to allow a current to conduct through the fixing film 1, elevating the temperature of the fixing film 1 to a predetermined value. Then, based on temperature information acquired by the temperature sensing element 6, the temperature is controlled. A recording material P with an unfixed toner image T is introduced, and at the fixing nip portion N, a toner image bearing surface of the recording material P is sandwiched and conveyed through the fixing nip portion N along with the fixing film 1. During this sandwiched conveyance process, the recording material P is heated by heat from the fixing film 1, and the unfixed toner image T on the recording material P is heated ad pressurized, and thus melted and fixed onto the recording material P. The recording material P having passed through the fixing nip portion N is curved and separated from the surface of the fixing film 1 and is discharged. The discharged recording material P is then conveyed by a discharging roller pair (not depicted in the drawings).
Effects of Embodiment 1
In a normal state in which no crack C is formed, currents I flow in the longitudinal direction, as depicted in
Now, a crack C is assumed to be formed in the fixing film 1.
In such a case, with no low-resistance layer 1e, flows of the currents I are blocked by the crack C, and thus, the currents I bypass the crack portion C, causing abnormal heat generation near ends of the crack C.
Reference characters I1 to I4 denote currents flowing through the heat generating layer 1a at a certain point of time. Provision of the conductive layers 1b allows currents I1 to U4 to flow uniformly, in the normal state, through the heat generating layer 1a of the fixing film 1 in the longitudinal direction, enabling uniform heat generation.
As depicted in
The portion in which abnormal heat generation has occurred has a much higher temperature than the normal portions, increasing the likelihood that the fixing film 1 will be thermally damaged or inappropriate images will be formed.
In contrast, in Embodiment 1, since a large number of the low-resistance layers 1e for equipotential surface formation are formed, even when a crack C is generated, the currents I bypass the crack C by passing through the low-resistance layers 1e as depicted in
As viewed in the thickness direction, as in
The low-resistance layers 1e are desirably continuous in the circumferential direction. The effects of the present invention can be exerted, however, even when the low-resistance layers 1e are partly discontinued. In other words, the linear low-resistance layers 1e are desirably provided that extend in the direction orthogonal to the currents I flowing in the longitudinal direction of the fixing film 1, or in the circumferential direction. The direction of the low-resistance layers 1e is not, however, limited to the orthogonal direction, and the effects of the present invention can be effected even when the low-resistance layers 1e are inclined relative to the currents I, so long as the low-resistance layers 1e extend in a direction traversing the currents I. The currents I flow between the conductive layers 1b provided at the opposite ends of the fixing film 1 in the longitudinal direction.
Furthermore, in the present embodiment, the low-resistance layers 1e are formed all over an area of the fixing film 1 over which the recording material P can be passed. Thus, wherever, in the heat generating layer 1a in the longitudinal direction, a crack C is formed as a result of foreign matter, a staple, or the like that rushes into the fixing apparatus along with the recording material P, abnormal heat generation can be reduced.
As described above, in Embodiment 1, a plurality of the low-resistance layers 1e that offers lower resistance than the heat generating layer 1a is formed on the heat generating layer 1a so as to traverse the currents I flowing through the heat generating layer 1a. This configuration enables a reduction in local current concentration when the heat generating layer 1a is cracked, resulting in a reduction in abnormal heat generation.
In the present example, the conductive layers 1b are provided. The present invention is not, however, limited to this configuration. Any configuration is possible, so long as the low-resistance layers 1e are formed in the areas of the heat generating layer 1a at least except for one end and the other end of the heat generating layer 1a.
Now, Embodiment 2 of the present invention will be described with reference to
Also in the present embodiment, first, a configuration of a fixing roller 10 will be described, and then, a fixing apparatus using the fixing roller 10 will be described.
Description of the Fixing Roller
The fixing roller 10 has a cored bar 10a serving as a rotating shaft, a sponge rubber layer 10b shaped like a roller, arranged concentrically and integrally around the cored bar 10a, and serving as an elastic layer, and a heat generating layer 10c provided on the sponge rubber layer 10b and containing, for example, a resin provided with conductivity by adding a conductive filler to the resin. Moreover, conductive layers 10d for power feeding having a predetermined width are formed on an inner surface of the heat generating layer 10c at respective opposite ends thereof. The width of each of the conductive layers 10d are set to, for example, approximately 10 mm. An elastic layer 10e and a release layer 10f are provided on the heat generating layer 10c. Furthermore, besides the conductive layers 10d provided on the heat generating layer 10c at the respective opposite ends thereof for power feeding, a large number of linear low-resistance layers 10g extending in the circumferential direction and configured to form an equipotential surface are formed along the longitudinal direction.
In a specific example, for example, a cored bar 10a formed of stainless steel and having an outside diameter of 11 mm was used, and for the sponge rubber layer 10b, an open-cell sponge rubber was used which was formed by containing resin balloons and a foaming agent in solid silicone rubber and vaporizing the foaming agent to join the resin balloons together. The heat generating layer 10c was the same as the heat generating layer 1a used for the fixing film 1 in Embodiment 1. The conductive layers 10d for power feeding were formed of the same material as the conductive layers 1b in Embodiment 1 and had the same thickness as the conductive layers 1b in Embodiment 1. However, the conductive layers 10d are formed on the inner surface of the heat generating layer 10c because the fixing roller 10 feeds power through an outer peripheral surface thereof. The elastic layer 10e and the release layer 10f were also formed of the same materials as the elastic layer 1c and the release layer 1d in Embodiment 1 and had the same thicknesses as those in Embodiment 1. The 10-mm areas at the longitudinally opposite ends of the heat generating layer 10c are not formed, however, because power is fed to the heat generating layer 10c through ends of the outer peripheral surface of the fixing roller 10. Areas at which the heat generating layer 10c is exposed are contact areas to which power is fed by the power feeding members 3a and 3b. The low-resistance layers 10g were also formed of the same material as the low-resistance layers 1e in Embodiment 1, had the same thickness and width as those in Embodiment 1, and were formed on the heat generating layer 10c between the conductive layers 10d at the same intervals as those in Embodiment 1.
Desirably, the fixing roller 10 in the present embodiment has an outside diameter of, for example, approximately 18 mm, and has a hardness of 30° to 70° under a load of 5.9 N as measured using an ASKER-C durometer, so as to achieve an appropriate fixing nip N and appropriate durability. Specifically, the hardness was set to 52°. Furthermore, as in the case of Embodiment 1, the heat generating layer 10c is 240 mm in length.
Description of the Fixing Apparatus
The fixing apparatus in Embodiment 2 includes a cylindrical fixing roller 10 serving as a heating rotating member, and a pressurizing roller 4 serving as a pressurizing member that forms a fixing nip N in cooperation with the fixing roller 10.
The fixing roller 10 and the pressurizing roller 4 are pressurized by pressuring means (not depicted in the figures) to form a fixing nip N with a predetermined width that is uniform in the longitudinal direction of the pressurizing roller 4. Furthermore, a non-contact temperature sensing element 6 is installed on the surface of the fixing roller 10 to detect the temperature of the fixing roller 10. Conduction of a current through the fixing roller 10 is controlled according to the temperature detected by the temperature sensing element 6.
Power feeding members 3a, 3b are connected to an AC power supply 50 through AC cables 7 and are disposed at ends of the fixing nip N located at the respective opposite portions thereof so as to be pressed toward and against the fixing roller 10. In the present embodiment, carbon brushes formed of metal graphite were used as the power feeding members 3a, 3b, as is the case with Embodiment 1. An AC voltage from an AC power supply 50 is applied to the carbon brushes via the AC cables 7 to achieve power feeding to the ends of the heat generating layer 10c of the fixing roller 10.
Specifically, the power feeding members 3a, 3b were pressed against the heat generating layer 10c of the fixing roller 10 over a width of 6 mm in the longitudinal direction and over a width of 6 mm in the conveying direction at a pressurizing force of 4 N.
A turning force from a driving mechanism portion (not depicted in the drawings) is transmitted to a driving gear G attached to the fixing roller 10 that is then rotationally driven at a predetermined speed in a counterclockwise direction, as depicted in
A current is conducted through the fixing roller 10 to elevate the temperature of the fixing roller 10 to a predetermined value. Then, the temperature is controlled by the temperature sensing element 6. A recording material P with an unfixed toner image T is introduced, and at the fixing nip portion N, a toner image bearing surface of the recording material P is sandwiched and conveyed through the fixing nip portion N along with the fixing roller 10. Then, a fixing operation is performed. The recording material P having passed through the fixing nip portion N is curved and is separated from the surface of the fixing roller 10, and then is discharged. The discharged recording material P is then conveyed by a discharging roller pair (not depicted in the drawings).
Effects of Embodiment 2
Also in Embodiment 2, a large number of the linear low-resistance layers 10g offering lower resistance than the heat generating layer 10c are formed on the heat generating layer 10c so as to traverse currents flowing through the heat generating layer 10c. In this configuration, a mechanism similar to the mechanism in Embodiment 1 enables a reduction in local current concentration when a crack C is formed in the heat generating layer 10c, resulting in a reduction in abnormal heat generation.
Furthermore, in Embodiment 2, the heat generating layer 10c is bonded to and backed up by the sponge rubber layer 10b, unlike in Embodiment 1 in which the heat generating layer 10c is shaped like a film. Thus, even if the heat generating layer 10c is damaged by a flaw, the configuration of Embodiment 2 enables a reduction in the likelihood that the damage will be developed as a result of the subsequent use of the fixing roller 10. This, in turn, enables a further reduction in the likelihood of abnormal heat generation.
In the present embodiment, the pressurizing roller 4 is used as the pressurizing member. A pressurizing film unit, however, using a driven pressuring film, for example, may be used as the pressurizing member.
Now, Embodiment 3 of the present invention will be described using
In Embodiment 3, a large number of the low-resistance layers 1e for equipotential surface formation are formed, as is the case with Embodiment 1. In the present embodiment, however, a heat generation distribution is varied in the longitudinal direction by setting the low-resistance layers 1e to have the same width, but varying the interval between the low-resistance layers 1e in the longitudinal direction. The remaining part of the configuration of Embodiment 3 is similar to the corresponding part of the configuration of Embodiment 1, and will thus not be described.
In areas in which the respective conductive layers 1b for power feeding are formed, substantially all the currents pass through the conductive layers 1b. Thus, the areas with the conductive layers 1b are substantially prevented from generating heat. Consequently, when a certain amount of time has elapsed since the start of temperature control, heat may travel to the ends of the fixing film 1, and temperature sagging may occur in which the temperature becomes lower in areas E of the fixing film 1 at the opposite ends thereof in the longitudinal direction than in the central portion of the fixing film 1 in the longitudinal direction. Prevention of this phenomenon can be achieved by increasing a heat generation density in the areas E. To change the heat generation density, means may be used, such as changing the thickness or the volume resistivity of the heat generating layer 1a only in the areas E. Such means may, for example, affect the strength of the fixing film 1, or make manufacturing difficult.
In Embodiment 3, the intervals at which the low-resistance layers 1e are formed are increased only in the areas E, each of which is located inside the area in which the conductive layer 1b is formed. Specifically, only for the low-resistance layers 1e in each area E that is 10 mm in size, the interval between the low-resistance layers 1e is changed from 0.4 mm to 0.9 mm with the width of each low-resistance layer 1e kept at 0.1 mm. As described in Embodiment 1, each low-resistance layer 1e has a lower volume resistivity than that of the heat generating layer 1a. Thus, the area in which the low-resistance layers 1e are formed has a lower resistance and a lower heat generation density than those of the area in which no low-resistance layer 1e is formed. When low-resistance layers 1e with a 0.9 mm interval and each with a width of 0.1 mm were formed all over the fixing film 1 in the longitudinal direction thereof, the fixing film 1 had a total resistance value of 18.7Ω. As described in Embodiment 1, when the low-resistance layers 1e with a 0.4 mm interval and each with a width of 0.1 mm are formed all over the fixing film 1 in the longitudinal direction thereof, the fixing film 1 has a resistance value of 18.0Ω. In the areas E in which the interval between the low-resistance layers 1e is locally increased to 0.9 mm, the resistance value is approximately 4% larger than the resistance value in the other portions of the fixing film 1, and thus, the amount of heat generated can accordingly be increased.
In Embodiment 3, the resistance is adjusted by varying the coating interval of the low-resistance layers 1e. The resistance can, however, be adjusted by varying a coating width of low-resistance layers 1e, that is, by varying the width of the low-resistance layers. In that case, portions in which the low-resistance layers 1e have a smaller width have a relatively large amount of heat generated, whereas portions in which the low-resistance layers 1e have a larger width have a relatively small amount of heat generated. Furthermore, both the interval and width of the low-resistance layers 1e may be varied. In short, the heat distribution in the longitudinal direction can be adjusted by locally varying at least one of the width of each low-resistance layer 1e and the interval between the low-resistance layers 1e. As described above, in addition to producing the effects of Embodiment 1, Embodiment 3 allows the resistance to be adjusted by varying the coating interval or the coating width of the low-resistance layers 1e, enabling the heat generation distribution to be easily adjusted.
Now, a configuration of a fixing film 20 in Embodiment 4 of the present invention will be described using
In Embodiment 4, a large number of the low-resistance layers 20e for equipotential surface formation are formed on the outer surface of a heat generating layer 20a as is the case with Embodiment 1. In the present embodiment, however, low-resistance layers 20f are also formed on an inner surface of the heat generating layer 20a, and the low-resistance layers 20f on the inner surface are each formed on the opposite side of a portion of the heat generating layer 20a in which no low-resistance layer 20e is present on the outer layer of the heat generating layer 20a.
The heat generating layer 20a is formed of a material offering higher resistance than the heat generating layer 1a in Embodiment 1. The volume resistivity of the heat generating layer 20a was adjusted to approximately 0.07 Ω·cm by dispersing carbon in polyimide. The thickness of the heat generating layer 20a was set to 75 μm. As a material for the low-resistance layers 20e, 20f, a silver paste with a volume resistivity of 4×10−5 Ω·cm was used, as is the case with Embodiment 1. For both the low-resistance layers 20e and 20f, the thickness was approximately 10 μm, both the interval and the width were 0.3 mm, and the pitch was 0.6 mm. The low-resistance layers 20e, 20f were formed such that the low-resistance layers 20e on the outer surface were shifted in phase from the low-resistance layers 20f on the inner surface by 0.3 mm. Conductive layers 20b, an elastic layer 20c, and a release layer 20d have configurations similar to the corresponding configurations in Embodiment 1 and will thus not be described.
In the present embodiment, the fixing film 20 has an actual resistance value of 17.8Ω at the opposite ends of the fixing film 20 in the longitudinal direction when the conductive layers 20b and the low-resistance layers 20e, 20f are formed on the heat generating layer 20a. The fixing film 20 has an actual resistance value of 36Ω at the opposite ends of the fixing film 20 in the longitudinal direction when only the conductive layers 20b are formed on the heat generating layer 20a. Thus, the total resistance of the fixing film 20 is reduced to approximately half by providing the low-resistance layers 20e, 20f on both surfaces of the heat generating layer 20a.
Furthermore, in the present embodiment, the low-resistance layers 20e on the outer surface and the low-resistance layers 20f on the inner surface are formed of the same silver paste. Different materials, however, may be used for the outer surface and for the inner surface so long as the materials have a smaller volume resistivity than that of the heat generating layer 20a.
In the normal state in which no cracking occurs, currents I flow alternately in the thickness direction of the heat generating layer 20a and through the low-resistance layers 20e or 20f in the longitudinal direction as depicted in
Now, a crack C is assumed to be formed in the fixing film 20.
In the present example, the low-resistance layer 20e or the low-resistance layer 20f is present at any portions of the heat generating layer 20a on the outer surface or inner surface thereof. Thus, wherever in the heat generating layer the crack C is formed, paths of currents I flowing through the low-resistance layers 20e, 20f in the longitudinal direction of the fixing film 20 are inevitably present, such as an encircled portion in
As described above, in Embodiment 4, a plurality of the low-resistance layers 20e and 20f that offer lower resistance than the heat generating layer 20a, are formed on the opposite surfaces of the heat generating layer 20a. A low-resistance layer 20e, 20f is present at many positions of the heat generating layer 20a on the outer surface or the inner surface thereof. When the heat generating layer 20a is cracked, the configuration, as described above, enables a reduction in local current concentration, allowing possible abnormal heat generation to be prevented.
Now, a configuration of a fixing film 30 in Embodiment 5 of the present invention will be described using
The high-resistance layer 30g is formed of a material offering higher resistance than a heat generating layer 30a. The volume resistivity of the high-resistance layer 30g was adjusted to approximately 0.3 Ω·cm by dispersing a slight amount of carbon in polyimide. The thickness of the high-resistance layer 30g was set to 50 μm. Then, conductive layers 30b and low-resistance layers 30f were formed on the high-resistance layer 30g, and the heat generating layer 30a was formed on the high-resistance layer 30g to a thickness of 85 μm. The heat generating layer 30a is formed of the same material as that of the heat generating layer 20a in Embodiment 4. A distance t1 in
As a material for the low-resistance layers 30e on the heat generating layer 30a and the low-resistance layers 30f on the high-resistance layer 30g, a silver paste with a volume resistivity of 4×10−5 Ω·cm was used, as is the case with Embodiment 4. For the low-resistance layers 30e and 30f, the thickness was approximately 10 μm, both the interval and the width were 0.3 mm, and the pitch was 0.6 mm. The low-resistance layers 30e, 30f were formed such that the low-resistance layers 30e were shifted in phase from the low-resistance layers 30f by 0.3 mm. An interval t2 between the low-resistance layers 30e and 30f in the thickness direction of the heat generating layer 30a is 75 μm. The distance between the low-resistance layers 30e, 30f on the same surface (30e-30e, 30f-30f) is 0.3 mm, and the distance between the low-resistance layers 30e, 30f in the thickness direction (30e-30f) is 75 μm. Both distances are the same as the corresponding distances in Embodiment 4, meaning that the resistance value in Embodiment 5 is the same as the resistance value in Embodiment 4.
Furthermore, in the present embodiment, the low-resistance layers 30e on the heat generating layer 30a and the low-resistance layers 30f on the high-resistance layer 30g are formed of the same silver paste. Different materials, however, may be used for the low-resistance layers 30e and for the low-resistance layers 30f, so long as the materials have a smaller volume resistivity than that of the heat generating layer 30a.
In Embodiment 4, if the low-resistance layers 20e, 20f are formed on the inner surface of the fixing film 20, since the fixing film inner surface is rubbed by the film guide 2 or the temperature sensing element 6 illustrated in
Embodiments 4 and 5, described above, may be applied to the fixing roller 10 described in Embodiment 2. Furthermore, in Embodiments 4 and 5, the width and the interval of the low-resistance layers 20e, 20f, 30e, 30f are the same for the inner peripheral surface and for the outer peripheral surface. The width and the interval of the low-resistance layers 20e, 20f, 30e, 30f may, however, locally vary, as disclosed in Embodiment 3 by way of example. The effects of the invention in Embodiments 4 and 5 can be produced so long as, in the thickness direction of the heat generating layer 20a, 30a, the low-resistance layer 20e, 20f, 30e, 30f is present at any positions of the heat generating layer 20a, 30a on the outer surface or the inner surface thereof.
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 is a continuation of U.S. patent application Ser. No. 15/578,858, filed Dec. 1, 2017, which is a U.S. national stage application of International Application No. PCT/JP2016/002883, filed Jun. 15, 2016, which claims priority from Japanese Patent Application No. 2015-125037, filed Jun. 22, 2015, and No. 2016-113423, filed Jun. 7, 2016. Each of the priority applications is hereby incorporated by reference herein in its entirety.
Number | Date | Country | |
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Parent | 15578858 | Dec 2017 | US |
Child | 16245606 | US |