Field of the Invention
The present invention relates to an image heating apparatus to be included in an image forming apparatus employing an electrophotographic system.
Description of the Related Art
Hitherto, as an image heating apparatus to be included in an image forming apparatus adopting an image forming process employing an electrophotographic system, an electrostatic recording system, or other systems, such as a copying machine and an LBP, there has been used one employing a film fixing system. In the image heating apparatus employing the film fixing system, a fixing film and a pressure roller (pressure member) are arranged in pressure-contact with each other, and a heating element for heating the fixing film is arranged to be brought into close contact with an inner surface of the fixing film at a portion at which the fixing film and the pressure member are opposed to each other (nip portion). As the heating element, a ceramic heater is generally used, which is obtained by forming a heat generating resistor on a substrate made of a ceramics such as alumina or aluminum nitride. The heat generating resistor, formed on the ceramic heater, inputs a current in a state obtained by subjecting a primary current flowing from an electrical outlet to power control by a control method such as wavenumber control or phase control in a power supply circuit, thereby generating heat and heating an image. The heating element is supported by a holder (support member) made of a resin or the like, and a temperature detecting element, a safety element, and the like are arranged in contact thereto. Those elements have functions such as input power control based on the detected temperature and current interruption during an abnormal temperature rise.
When the above-mentioned film-heating fixing device including the heating element carries out an operation of heating and fixing an unfixed toner image onto a recording material having a small width in a longitudinal direction (a direction orthogonal to a conveyance direction of the recording material, width direction of the recording material) (small-sized sheet), there is a difference in the heat radiation amount of the film in the longitudinal direction. In other words, a part of the film that is brought into contact with the recording material loses heat to the recording material, but a part that is not brought into contact with the recording material does not lose heat to the recording material. Therefore, at the nip portion, there is caused a phenomenon that the temperature of a region through which the recording material does not pass (non-sheet-passage portion) is higher than the temperature of a region through which the recording material passes (sheet-passage portion), which is what is called non-sheet-passage portion temperature rise. The occurrence of the non-sheet-passage portion temperature rise causes image defects due to temperature unevenness at the nip, wrinkled sheets due to thermal expansion of the pressure roller in the non-sheet-passage portion, sheet conveyance failure, and the like. Further, thermal deterioration of parts of the film and the pressure member corresponding to the non-sheet-passage portion may progress, which may result in damage.
In order to solve the problem of the non-sheet-passage portion temperature rise, in Japanese Patent Application Laid-Open No. H11-84919, there is proposed a configuration in which a high heat conductive member is mounted between the heater substrate and the support member, to thereby obtain a uniform heater temperature distribution in the longitudinal direction. Further, in Japanese Patent Application Laid-Open No. 2014-123100, in order to secure safe use of the high heat conductive member, there is proposed a configuration in which two high heat conductive members are arranged in the longitudinal direction, and one high heat conductive member is brought into contact with a thermistor, while the other high heat conductive member is brought into contact with a fuse. In this configuration, the primary side and the secondary side of the power supply circuit of the image forming apparatus are electrically separated from each other.
In the configuration in which a single high heat conductive member continuous in the longitudinal direction is used as in Japanese Patent Application Laid-Open No. H11-84919, a metal plate (for example, aluminum plate) used as the high heat conductive member is formed into an elongated shape in accordance with the size of the heater, and hence there is a fear of the occurrence of warpage. When warpage occurs, the degree of contact of the high heat conductive member to the heater substrate may become non-uniform in the longitudinal direction.
In the configuration in which a plurality of high heat conductive members are arranged as in Japanese Patent Application Laid-Open No. 2014-123100, the fear of a reduction in the degree of contact between the high heat conductive member and the heater substrate due to the occurrence of warpage is reduced, but a gap is formed between the two high heat conductive members, and hence there arises a new fear in heat conduction uniformity.
According to a first exemplary embodiment of the present invention, there is provided an image heating apparatus for heating a toner image formed on a recording material while conveying the recording material at a nip portion. The portion, the image heating apparatus includes: a film having a tubular shape; a backup member configured to be brought into contact with an outer surface of the film to form the nip portion; a heater having an elongated shape and being configured to be brought into contact with the film, the heater including a substrate and a heat generating resistor formed on the substrate; a first heat conductive member having a higher thermal conductivity than the substrate and being configured to be brought into contact with a surface of the heater opposite to a surface of the heater that is brought into contact with the film, the first heat conductive member including a plurality of divided first heat conductive members arranged in a longitudinal direction of the heater with a gap formed therebetween; a pinching member configured to pinch the first heat conductive member together with the heater in a thickness direction of the heater; and a second heat conductive member provided in a region of the gap so as to be brought into contact with both of the heater and the pinching member.
According to a second exemplary embodiment of the present invention, there is provided an image heating apparatus for heating a toner image formed on a recording material while conveying the recording material at a nip portion. The image heating apparatus includes: a film having a tubular shape; a backup member configured to be brought into contact with an outer surface of the film to form the nip portion; a heater having an elongated shape and being configured to be brought into contact with the film, the heater including a substrate and a heat generating resistor formed on the substrate; a first heat conductive member having a higher thermal conductivity than the substrate and being configured to be brought into contact with a surface of the heater opposite to a surface of the heater that is brought into contact with the film, the first heat conductive member including a plurality of divided first heat conductive members arranged in a longitudinal direction of the heater with a gap formed therebetween; a pinching member configured to pinch the first heat conductive member together with the heater in a thickness direction of the heater; and a second heat conductive member provided in a region of the gap so as to be brought into contact with both of two of the plurality of divided first heat conductive members, which are opposed to each other across the gap.
Further features of the present invention will become apparent from the following description of exemplary embodiments with reference to the attached drawings.
Exemplary embodiments of the present invention are described below in detail according to various examples with reference to the attached drawings. Note that, the dimensions, materials, shapes, relative positional relationship, and the like of structural components described herein may be appropriately changed depending on the structure of the apparatus to which the present invention is applied and various conditions. Specifically, the scope of the present invention is not meant to be limited to the following embodiments.
<Example 1>
An image heating apparatus according to an example of the present invention is to be included in an image forming apparatus such as a laser beam printer employing an electrophotographic process, and is an apparatus configured to fix an unfixed toner image (developer image) formed on a recording material by the electrophotographic process onto the recording material. Such fixing processing is carried out while conveying the recording material, and the recording material is conveyed in a manner that the center of the recording material in a direction orthogonal to a recording material conveyance direction matches a center reference of a recording material conveyance path. In the following description of the apparatus configuration, the longitudinal direction refers to a direction orthogonal to the recording material conveyance direction in a recording material conveyance path plane, and also refers to a width direction of the recording material to be conveyed. A transverse direction refers to the same direction as the recording material conveyance direction, and also refers to the length direction of the recording material to be conveyed. Note that, the configuration of the image forming apparatus into which the image heating apparatus according to this example is incorporated (configuration other than a heating and fixing portion, such as an image forming portion) is similar to the related art, and thus description thereof is omitted herein.
(Fixing Apparatus (Image Heating Apparatus))
The fixing apparatus 18 includes a film unit 31 including a flexible tubular film 36 (fixing member), and a pressure roller 32 serving as a pressure member. The film unit 31 and the pressure roller 32 are arranged substantially parallel to each other between right and left side plates 34 of an apparatus frame 33 so that a heater 37 is opposed to the pressure roller 32 through intermediation of the film 36.
The pressure roller 32 includes a metal core 32a, an elastic layer 32b formed on the outer side of the metal core 32a, and a releasing layer 32c formed on the outer side of the elastic layer 32b. As the material of the elastic layer 32b, silicone rubber or fluoro-rubber is used. As the material of the releasing layer 32c, PFA, PTFE, or FEP is used. In this example, the following pressure roller 32 was used. Specifically, on the stainless-steel metal core 32a having an outer diameter of 11 mm, the silicone rubber layer 32b having a thickness of about 3.5 mm was formed by injection molding, and the outer side thereof was covered with the PFA resin tube 32c having a thickness of about 40 μm. The outer diameter of the pressure roller 32 is 18 mm. The hardness of the pressure roller 32 is desired to be within a range of from 40° to 70° when being measured with an Asker-C hardness tester under a load of 9.8 N from viewpoints of securing a nip N and durability. In this example, the hardness is adjusted to 54°. The longitudinal length of the elastic layer of the pressure roller 32 is 226 mm.
As illustrated in
As illustrated in
The substrate 37a of the heater 37 of this example has a cuboid shape with a longitudinal length of 270 mm, a transverse length of 5.8 mm, and a thickness of 1.0 mm, and is made of alumina (thermal conductivity of 20 W/(mK)). The heat generating resistors 37b form a pattern of being folded at a longitudinal end portion via an electrical contact portion 37e, and have the same shape on both of the upstream side and the downstream side in the recording material conveyance direction. The heat generating resistors 37b each have a longitudinal length of 222 mm and a transverse length of 0.9 mm. Further, the position in the transverse direction of the heat generating resistor 37b is positioned 0.7 mm from the end of the ceramic substrate 37a on both of the upstream side and the downstream side, and the heat generating resistors 37b are printed at positions symmetric about the transverse center. Note that, grease having heat resistance is applied onto the inner surface of the film 36 so as to improve the sliding performance of the heater 37 and the support member 38 with respect to the inner surface of the film 36.
In the thermistor 43 (temperature detecting member), in order to stabilize a contact state between a casing of the thermistor 43 and the metal plate 39 (another of the first heat conductive members), a thermistor element is arranged under a state in which ceramic paper or the like is interposed between the casing and the metal plate 39, and the thermistor element is further covered with an insulating material such as a polyimide tape. The thermal fuse 44 (current cut-off member) is a component configured to be actuated when sensing abnormal heat generation of the heater in response to an abnormal temperature rise of the heater 37, to thereby interrupt energization to the heater 37. In the thermal fuse 44, a fuse element that melts at a predetermined temperature is mounted in a cylindrical metal casing, and when the fuse element is fused due to an abnormal temperature rise of the heater 37, a circuit for energizing the heater 37 is interrupted. The thermal fuse 44 is mounted on the metal plate 40 (one of the first heat conductive members) via thermal conductive grease, to thereby prevent operation failure due to rising of the thermal fuse 44 with respect to the heater 37.
As illustrated in
As illustrated in
When the fixing apparatus 18 is operated, a rotational force is transmitted from the drive source (not shown) to the drive gear G for the pressure roller 32 so as to rotationally drive the pressure roller 32 at a predetermined speed in a clockwise direction in
Under a state in which the film 36 is rotated and the heater 37 is energized so that the temperature of the heater 37 detected by the thermistor 43 reaches a target temperature, a recording material P is introduced. A fixing entrance guide 30 plays the role of guiding the recording material P carrying a toner image t in an unfixed state toward the nip portion N. The recording material P introduced into the nip portion N has its surface carrying the unfixed toner image t brought into close contact with the film 36 at the nip portion N, and is nipped and conveyed through the nip portion N together with the film 36. In this conveyance process, due to the heat of the film 36 heated by the heater 37, the unfixed toner image t on the recording material P is heated and pressurized onto the recording material P to be melted and fixed. The recording material P that has passed through the nip portion N is self-stripped from the surface of the film 36, to thereby be delivered outside the apparatus by a delivery roller pair (not shown). Note that, the maximum sheet passable width of the fixing apparatus in this example is 216 mm, and an LTR-sized recording material can be printed at a speed of 20 PPM.
(Characteristics of Example)
With reference to
As illustrated in
The longitudinal center portion of the heater 37 is supported by the support member 38 through the intermediation of the metal plates 39 and 40, and the longitudinal end portions of the heater 37 are supported in contact with the support member 38.
As illustrated in
As illustrated in
With reference to
(Behavior of Example)
As a result of printing an image under this state, in the Comparative Example, hot offset occurred at the gap portion between the aluminum plates when the first sheet was printed. This was caused because the temperature of the back side of the heater was locally increased and the film surface temperature at this position was increased as well. When the film surface temperature of the Comparative Example was measured with a radiation thermometer, it was understood that the temperature of the part B was higher than that of the part A by about 5° C. immediately before the printing of the first sheet. This hot offset remarkably occurs immediately after the temperature of the image heating apparatus rises to the fixing temperature from a state in which the image heating apparatus is sufficiently cooled at normal temperature. When printing is repeated, the temperature on the back side of the heater is equalized, and hence the hot offset is gradually eliminated. In the Comparative Example, the hot offset becomes mild in the second sheet, and is eliminated in the third sheet.
Then, in this example, the temperature on the back side of the heater became more uniform as compared to the Comparative Example, thereby being capable of obtaining a satisfactory image even in the first sheet without causing the hot offset. This is because a gap between the aluminum plates 39 and 40 is filled with the grease 50, and heat is conducted from the back side of the heater 37 to the support member 38 through the grease 50 even in the gap portion between the aluminum plates 39 and 40, thereby preventing the back side of the heater 37 from locally increasing in temperature at the gap portion.
Note that, in this example, SC102 was employed, as the grease, but when SC4476cv (thermal conductivity: 3.1 W/(mK), produced by Dow Corning Toray Co., Ltd.) or the like, which is better in thermal conductivity than SC102, is used, the temperature difference on the back side of the heater is further reduced. Further, grease such as HP300 (thermal conductivity: 0.2 W/(mK), produced by Dow Corning Toray Co., Ltd.), which is lower in thermal conductivity than SC102, may be used. Also in this case, thermal conduction is increased as compared to the case of air having a thermal conductivity of 0.025 W/(mK), which corresponds to a case where an air layer is formed between the heater 37 and the support member 38. Therefore, the effect can be obtained at a certain level. All of those greases have an insulating property. When the metal plates are electrically separated from each other for the reason described in Example 7 of Japanese Patent Application Laid-Open No. 2014-123100, the grease is required to have the insulating property. On the other hand, when the metal plates are separated from each other not for electrical separation but for avoiding occurrence of warpage, conductive grease may be used without a problem. However, when the thermal conduction property is excessively high, there is a fear in that the effect of separating the metal plates, which has been originally made from the viewpoint of the lateral difference in heat capacity of the image heating apparatus, is reduced. Therefore, it is preferred that a type of the grease having the optimum physical property be selected depending on the purpose.
As described above, according to the configuration of this example, the grease is applied between the high heat conductive members, thereby being capable of suppressing the temperature rise of the heater at a region between the high heat conductive members. With this arrangement, while maintaining the heat equalizing effect of the high heat conductive member of the related art, the occurrence of the hot offset due to the local temperature rise of the heating element is prevented, thereby rendering the apparatus capable of obtaining a satisfactory image.
In this example, two first heat conductive members are arranged to be separated from, each other in the longitudinal direction, but the number of the first heat conductive members to be provided is not particularly limited. Three or more first heat conductive members may be arranged to be separated from, each other in the longitudinal direction within a range capable of reducing the influence of the warpage of the metal plates and suitable for formation of a uniform temperature distribution in the longitudinal direction. In this case, the second heat conductive member may be provided at each gap between the first heat conductive members. Further, how the gap between the first heat conductive members is filled with the second heat conductive member is not required to satisfy a state in which, for example, the gap portion between the first heat conductive members is completely filled with the second heat conductive member as long as the above-mentioned local temperature rise can be suppressed. That is, it is only required to secure such a configuration that, at the gap portion, a space between the heater and the support member is filled (connected) so as to enable thermal conduction. Further, as long as the thermal conductivity of the second heat conductive member is higher than at least the thermal conductivity of air, the relationship with respect to the thermal conductivity of the substrate or the first heat conductive member may be appropriately set within a range capable of suppressing the above-mentioned local temperature rise. The size of the gap between the first heat conductive members and other various dimensional relationships may also be appropriately set as long as a uniform temperature distribution can be obtained in the longitudinal direction.
<Example 2>
In Example 2 of the present invention, there is described an example of a case where an elastic member is used as the second heat conductive member provided between the plurality of first heat conductive members. The schematic configuration of the fixing apparatus in this example is the same as Example 1. Therefore, a description of the common configuration is omitted, and only a characteristic part of this example is described.
(Characteristics of Example)
(Action of Example)
A fixing apparatus according to a Comparative Example of this example has the same configuration as the Comparative Example of Example 1 illustrated in
As a result of printing an image under this state, in the Comparative Example, hot offset occurred at the gap portion between the aluminum plates when the first sheet was printed. The hot offset became mild in the second sheet, and was eliminated in the third sheet. Then, in this example, the temperature on the back side of the heater was more equalized as compared to the Comparative Example, and the hot offset did not occur even in the first sheet, thereby being capable of obtaining a satisfactory image. This is because a gap between the aluminum plates 39 and 40 is filled with the compressed silicone rubber 51, and heat is conducted from the back side of the heater 37 to the support member 38 through intermediation of the silicone rubber 51 even at the gap portion between the aluminum plates 39 and 40, thereby preventing the back side of the heater 37 from locally increasing in temperature at the gap portion.
Note that, in this example, silicone solid rubber is employed as the second heat conductive member, but elastic members such as foamed rubber and sponge may be employed. Such elastic members have a lower thermal conductivity than solid rubber, but the thermal conduction is better than the case of air having the thermal conductivity of 0.025 W/(mK), which corresponds to a case where an air layer is formed between the heater 37 and the support member 38. Therefore, the effect can be obtained at a certain level. When the metal plates are electrically separated from each other for the reason described in Example 7 of Japanese Patent Application Laid-open No. 2014-123100, the elastic member is required to have the insulating property. When the metal plates are separated from each other not for electrical separation but for avoiding occurrence of warpage, a conductive elastic member may be used without a problem. Therefore, it is preferred that an elastic member having the optimum physical property be selected depending on the purpose.
As described above, according to the configuration of this example, the elastic member is arranged between the high heat conductive members, thereby allowing the apparatus to suppress the temperature rise of the heater at a region between the high heat conductive members. With this arrangement, while maintaining the heat equalizing effect of the high heat conductive member of the related art, the occurrence of the hot offset due to the local temperature rise of the heating element is prevented, thereby rendering the apparatus capable of obtaining a satisfactory image.
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. 2014-231522, filed Nov. 14, 2014, which is hereby incorporated by reference herein in its entirety.
Number | Date | Country | Kind |
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