The present disclosure relates to a fixing apparatus for use in image forming apparatuses, such as electrophotographic copying machines and laser printers.
The following configuration is known as the configuration of fixing apparatuses for use in electrophotographic image forming apparatuses. This configuration includes a tubular film, a heater in contact with the film, and a pressure roller that forms a nip together with the heater, with the film therebetween. A printing material that carries an unfixed toner image is heated at the nip while being conveyed, so that the toner image is fixed to the printing material.
When the film of the fixing apparatus is rotated at high speed to cope with high-speed printing, heat supply from the heater to the film cannot be sometimes completed in time, and a configuration is disclosed in which heat can be transferred from the heater to the film also from other than the surface of the heater in contact with the film (PTL 1). Specifically, a heat conducting member (metal plate) is in contact with a surface of the heater opposite to the surface in contact with the film, and the heat conducting member is in contact with the film. This configuration enables higher speed fixing processing.
However, a fixing apparatus that can transfer heat from the heater to the film at still higher speed is required.
[PTL 1]
Japanese Patent Laid-Open No. 2003-257592
A fixing apparatus for solving the above problem according to an aspect of the present disclosure is configured to heat a toner image to fix the toner image to a printing material. The apparatus includes a tubular film, an elongate plate-like heater, a heat conducting member, and a support member. The elongate plate-like heater includes a first surface in contact with an inner surface of the film and a second surface opposite to the first surface. The heat conducting member is long in a longitudinal direction of the heater and is in contact with the second surface of the heater. The support member is capable of rotating the film while supporting the heater, with the heat conducting member therebetween. The heat conducting member includes an extending portion extending, outside an upstream end of the heater in a rotational direction of the film, in a direction from the second surface of the heater toward the first surface. The extending portion includes a contact portion protruding from the first surface of the heater toward the film into contact with the film.
Further features of the present invention will become apparent from the following description of exemplary embodiments with reference to the attached drawings.
A fixing apparatus according to a first embodiment of the present disclosure will be described hereinbelow with reference to the drawings. First, the overall configuration of an image forming apparatus of the present embodiment will be described, and then the fixing apparatus will be described.
[Image Forming Apparatus Main Body]
In the present embodiment, an example of a method for forming an unfixed toner image on a printing material and the image forming apparatus will be described with reference to a schematic diagram illustrated in
(Fixing Apparatus)
The fixing apparatus 100 of the present embodiment will be described hereinbelow.
The fixing apparatus 100 includes a fixing film 112, a heater 113, a heater holder 130, a pressure roller 110, and a heat conducting member 140.
The heater 113 is in contact with the inner surface of the fixing film 112 to heat the fixing film 112. The pressure roller 110 forms a nip N together with the heater 113, with the fixing film 112 therebetween. When the pressure roller 110 is driven in the direction of arrow R1 in the drawing, the fixing film 112 is rotated in the direction of arrow R2 by receiving a frictional force at the nip N from the pressure roller 110. When the printing material P to which an unfixed toner image T is transferred is conveyed from the direction of arrow A1 in the drawing to the nip N, the toner image T is thermally fixed to the printing material P.
The fixing film 112 will be described. The tubular fixing film 112 is configured so as to be rotatable and has a cylindrical shape with an outside diameter of 18 mm under no external force. The fixing film 112 has a multilayer configuration in the thickness direction. The fixing film 112 includes abase layer and a releasing layer formed on the outside of the base layer. The material of the base layer is metal, such as stainless steel or nickel, or a heat-resistant resin, such as polyimide, in consideration of heat resistance and rigidity. In the present embodiment, a polyimide resin is used as the material of the base layer of the fixing film 112, to which a carbon-based filler is added to increase the heat conductivity and strength. The thinner the base layer, the easier the heat from the heater 113 is transferred to the surface of the fixing film 112. However, this decreases its strength, and therefore, the thickness is preferably about between 15 μm and 100 μm, and in the present embodiment, it is set at 50 μm. The material of the releasing layer may be fluororesin, such as a perfluoroalkoxy (PFA) resin, a polytetrafluoroethylene (PTFE), or a tetrafluoroethylene-hexafluoropropylene (FEP) resin. In the present embodiment, PFA, which has high releasability and heat resistance among fluororesins, is used. The releasing layer may be a coating tube or a coat of paint. In the present embodiment, the releasing layer is made of a coat having a good thin-wall molding characteristic. The thinner the releasing layer, the easier the heat from the heater 113 is transferred to the surface of the fixing film 112. However, if the release layer is too thin, its durability decreases. For that reason, the thickness is preferably about between 5 μm and 30 μm. In the present embodiment, the thickness is set at 10 μm. An elastic layer may be disposed between the base layer and the releasing layer, although it is not provided in the present embodiment. In this case, the material of the elastic layer is silicone rubber or fluororubber.
The pressure roller 110 will be described. The pressure roller 110 has an outside diameter of 20 mm and includes a metal core 117 with a diameter of 12 mm and an elastic layer 116 with a thickness of 4 mm formed on the metal core 117. The material of the elastic layer 116 is solid rubber or foamed rubber. The foamed rubber has low heat capacity and low heat conductivity, so that the heat of the surface of the pressure roller 110 is hardly absorbed into the inside. This has an advantage in that the surface temperature tends to rise, reducing the rise time. In the present embodiment, foamed silicone rubber is used. The smaller the outside diameter of the pressure roller 110, the smaller the heat capacity is. However, a too small diameter causes a decrease in the width of the pressure nip N, and therefore an appropriate diameter is needed. In the present embodiment, the outside diameter is set at 20 mm. Also for the thickness of the elastic layer 116, a too small thickness causes the heat to escape to the metal core 117, and therefore an appropriate thickness is needed. In the present embodiment, the thickness of the elastic layer 116 is set at 4 mm. A releasing layer 118 made of a perfluoroalkoxy (PFA) resin is formed on the elastic layer 116 as a toner releasing layer. The releasing layer 118 may be a coating tube or a coat of paint, like the releasing layer of the fixing film 112. In the present embodiment, a tube having high durability is used. The material of the releasing layer 118 may be not only PFA but also a fluororesin, such as PTFE, FEP, or fluororubber or silicone rubber having high releasability. The lower the surface hardness of the pressure roller 110, the larger the width of the nip N. In the present embodiment, pressure rollers 110 at three levels of 48°, 50°, and 52° of Asker-C hardness (load: 4.9 N) were used to verify the relationship between variations in the width of the nip N (described later) and the heat conduction of the heat conducting member 140. The pressure roller 110 is pressed to the heater 113 by a pressure unit (not illustrated). Also for the pressing force, a total pressure of three levels of 13 kgf, 14 kgf, and 15 kgf were used to verify the variations of the nip N (described later) and the heat conduction of the heat conducting member 140. The pressure roller 110 is configured to be rotated in the direction of arrow R1 at a surface moving speed of 200 mm/sec by a rotating unit (not illustrated).
The heater 113 will be described. The heater 113 is a heater in which a heating resistor is disposed on a substrate made of ceramic, such as alumina or aluminum nitride. The heater 113 is an elongate plate-like member having a first surface 113a in contact with the inner surface of the fixing film 112 and a second surface 113b opposite to the first surface 113a. The heater 113 is a heater in which the surface of an alumina substrate with a width of 6 mm in the printing-material conveying direction and a thickness of 1 mm is coated with a heating resistor made of Ag/Pd (silver-palladium) having a thickness of 10 μm by screen printing, on which 50-μm thick glass serving as a heating-element protecting layer is disposed.
The heater holder 130 will be described. The heater holder 130 is a support member that supports the second surface 113b of the heater 113. The heater holder 130 is made of liquid crystal polymer, which is a heat resistant resin, or the like.
The heat conducting member 140, which is a feature of the present embodiment, will be described.
Next, the definition of the protrusion amount h of the extending portion 140b will be described with reference to
In order to stably transfer heat from the heater 113 to the fixing film 112 through the extending portion 140b, it is important to configure the extending portion 140b and the fixing film 112 so that the state of contact therebetween is stabilized. In the present embodiment, the contact state between the extending portion 140b and the fixing film 112 is stabilized by providing the protrusion amount h.
In the present embodiment, the contact state between the extending portion 140b and the fixing film 112 was evaluated under the following three conditions. The first condition is that the pressing force at the nip N is small, and the roller hardness is high, so that the width of the nip N is decreased (pressing force: 13 kgf, roller hardness: 52°, pressure nip width: 5 mm). The second condition is that the pressing force at the nip N is large, and the roller hardness is low, so that the width of the nip N is increased (pressing force: 15 kgf, roller hardness: 48°, nip width: 7 mm). The third condition is that both of the pressing force at the nip N and the roller hardness are intermediate values of the values of the above conditions (pressing force: 14 kgf, roller hardness: 50°, nip width: 6 mm). The stability of the contact state between the extending portion 140b and the film 112 was evaluated under the above three conditions.
A method of evaluation will be described. The evaluation was conducted in an environment of a room temperature of 23° C. and a relative humidity of 50%. The heater 113 is left for about one hour without being supplied with electric power, and a sheet of paper with a stripe image (2-dot/3-space) was passed to check fixing unevenness. The paper used was XEROX Vitality (75 g/m2, LTR).
In the present embodiment, the heat conducting member 140 having a protrusion amount h of 100 μm was used for evaluation. For comparison, Comparative Example 1 in which the protrusion amount h of the heat conducting member is −100 μm and Comparative Example 2 in which the protrusion amount is 0 μm were used.
The results of comparison under the above conditions are shown in Table 1. First, in Comparative Example 1 in which the protrusion amount h is −100 μm, fixing unevenness was exhibited at all the nip widths. This is because, when the track of the fixing film 112 in the vicinity of the nip N bends in a direction opposite to the pressure roller 110, the extending portion 140b and the fixing film 112 are brought into contact with each other to transfer heat, but when the fixing film 112 bends toward the pressure roller 110, the extending portion 140b and the fixing film 112 do not come into contact with each other, so that heat is not transferred. Next, in Comparative Example 2 in which the protrusion amount h is 0 μm, when the width of the nip is 7 mm, the fixing unevenness was reduced to a trouble-free level. This is because the width of the heater 113 smaller than the width of the nip N causes the extending portion 140b and the inner surface of the fixing film 112 to come into contact al the time at the nip N in the vicinity of the heater 113 to enable heat transfer. However, in the cases where the pressure nip width is 6 mm and 5 mm, fixing unevenness occurred for the same reason as in Comparative Example 1. Finally, in the embodiment in which the protrusion amount h was 100 μm, the fixing unevenness was reduced to a problem-free level at all the widths of the nip N. This is because the large protrusion of the extending portion 140b allows the protrusion amount h of the extending portion 140b to be larger than the amount of change of the track of the fixing film 112, so that even when the track of the fixing film 112 changes, the contact between the extending portion 140b and the inner surface of the film 112 is kept.
In the above description, the extending portion 140b of the heat conducting member 140 is disposed upstream of the heater 113 in the printing-material conveying direction, but this is given for mere illustration. The temperature of the fixing film 112 is lower on the upstream than on the downstream of the heater 113 in the printing-material conveying direction. For that reason, disposing the extending portion 140b upstream enables efficient heat transfer from the extending portion 140b to the fixing film 112.
In the modifications, the extending portions 140c on the upstream side and the downstream side in the printing-material conveying direction may have different shapes. Any shape may be selected, for example, the extending portion 140b on the upstream side is Z-shaped, and the extending portion 140b in the downstream side is L-shaped.
As described above, in the present embodiment, fixing unevenness can be prevented regardless of the rotation track of the fixing film 112 by protruding the extending portion 140b from the sliding surface of the heater 113 toward the pressure roller 110.
The configuration of the present embodiment is similar to the configuration of the first embodiment except that the shape of the heater holder 130 differs. Therefore, a description of the configuration other than the configuration of the heater holder 130 will be omitted.
In the present embodiment, the protrusion amount h of an extending portion 140b is set at 100 μm, as in the first embodiment. The present embodiment includes a restricting portion 150 for restricting the rotation track of the fixing film 112 on the upstream side of the extending portion 140b in the rotational direction of the fixing film 112 (the printing-material conveying direction). The restricting portion 150 is disposed at the heater holder 130 and extends in a direction from the second surface 113b of the heater 113 toward the first surface 113a on the outside of the upstream end of the extending portion 140b of the heat conducting member 140 in the rotational direction of the fixing film 112. The restricting portion 150 protrudes toward the fixing film 112 further than the extending portion 140b.
The definition of the protrusion amount h′ of the restricting portion 150 will be described with reference to
The advantageous effect of the restricting portion 150 of the heater holder 130 will be evaluated. In the present embodiment, the evaluation was performed in a low-temperature environment to perform the evaluation under further sever conditions. In a low-temperature environment, the amount of heat transferred from the heater 113 and the extending portion 140b to the fixing film 112 is larger than in an ordinary-temperature environment. Therefore, fluctuations in the contact area between the extending portion 140b and the fixing film 112 cause fixing unevenness. The configuration of the present embodiment has the effect of stabilizing the state of contact between the fixing film 112 and the heat conducting member 140.
A method of evaluation in the present embodiment is similar to that of the first embodiment except the evaluation environment. The evaluation was conducted in a low-temperature low-humidity environment of a room temperature of 15° C. and a relative humidity of 10%. The heater 113 is left for about one hour without being supplied with electric power, and a sheet of paper with a stripe image (2-dot/3-space) was passed to check fixing unevenness. The paper used was XEROX Vitality (75 g/m2, LTR).
With the configuration of the present embodiment, changes in the rotation track of the fixing film 112 can be reduced or eliminated by bending the rotation track of the fixing film 112 in advance using the restricting portion 150, so that the fluctuation in the contact area between the fixing film 112 and the extending portion 140b can be prevented.
Another advantage of providing the restricting portion 150 is that an edge 140c of the extending portion 140b on the upstream side in the printing-material conveying direction is prevented from coming into contact with the fixing film 112. In the case where the rotation track of the fixing film 112 follows the extending portion 140b, as illustrated in
Although the extending portion 140b of the heat conducting member 140 is disposed on the upstream side of the heater 113 in the printing-material conveying direction, as in the first embodiment, this is given for mere illustration. In other words, the present embodiment can also be applied to a case in which the extending portion 140b is disposed downstream in the rotational direction of the fixing film 112 (printing-material conveying direction) from the heater 113, as in Modification 1 of the present embodiment, illustrated in
A third embodiment of the present disclosure will be described hereinbelow. The configuration of the third embodiment is similar to the configuration of the first embodiment except that the shapes of the extending portion 140b of the heat conducting member 140 and the heater holder 130 differ. Therefore, a description of the details of the configuration of the fixing apparatus 100 will be omitted.
A restricting portion 150 of the present embodiment will be described with reference to
Although the extending portion 140b of the heat conducting member 140 is disposed on the upstream side of the heater 113 in the printing-material conveying direction, as in the first embodiment, this is given for mere illustration. The extending portion 140b may be disposed downstream from the heater 113 in the printing-material conveying direction), as in Modification 1 of the present embodiment, illustrated in
In the present embodiment, the configuration of the longitudinal end of the extending portion 140b of the heat conducting member 140 and the heater holder 130 will be described with reference to
In the case where the heat conducting member 140 is made of a metal plate, such as an aluminum alloy, the heat conducting member 140 is often manufactured by press working. Therefore, when the edge of the longitudinal end face 140d of the heat conducting member 140 slides while being in close-contact with the fixing film 112, the fixing film 112 is prone to be scraped.
To solve the above problem, the present embodiment is characterized in that the heater holder 130 includes a film contact surface 130a outside the longitudinal end face 140d of the heat conducting member 140 in the longitudinal direction of the heater 113, as illustrated in
Although one longitudinal end of the fixing film unit 1000 in
In the present embodiment, the extending portion 140b of the heat conducting member 140 is disposed upstream from the heater 113 in the printing-material conveying direction. This is because the temperature of the fixing film 112 is lower on the upstream side of the heater 113 in the printing-material conveying direction than on the downstream side, so that disposing the extending portion 140b on the upstream side enables efficient heat transfer from the extending portion 140b to the fixing film 112. However, the extending portion 140b may be disposed downstream of the heater 113 in the printing-material conveying direction, like the configuration illustrated in
Alternatively, by combining the configurations illustrated in
In the present embodiment and the modification of the present embodiment, one end of the film unit in the longitudinal direction has been described. The same configuration applies to the other end.
The same advantageous effects can be obtained by using the configurations of the present embodiment and the modification of the present embodiment for the heat conducting members of the second and third embodiments.
Unlike the first embodiment, the present embodiment includes a temperature sensor (thermistor) 115 for detecting the temperature of the heater 113 or the fixing film 112 and is configured to control electric power to be supplied to the heating resistor of the heater 113 in response to a signal from the thermistor 115. Differences from the configuration of the first embodiment will be described with reference to
(Fixing Apparatus)
A fixing apparatus 100 of the present embodiment will be described hereinbelow.
Next, the thermistor 115 serving as a temperature sensor, illustrated in
In order to detect a change in the temperature of the fixing film 112 via the heat conducting member 140 with the thermistor 115, the extending portion 140b of the heat conducting member 140 may be stably in contact with the fixing film 112. However, since the fixing film 112 is a flexible member, the position of the fixing film 112 in the thickness direction can fluctuate during rotation. At that time, the contact area between the extending portion 140b of the heat conducting member 140 and the fixing film 112 fluctuates.
In the present embodiment, a surface of the extending portion 140b in contact with the fixing film 112 protrudes in the direction of arrow a by the protrusion amount h with respect to the first surface 113a of the heater 113 so that fluctuations in the contact area between the extending portion 140b of the heat conducting member 140 and the fixing film 112 are reduced. This enables the change in the temperature of the fixing film 112 to be detected by the thermistor 115 with high responsiveness.
When the printing material reaches the nip N, it derives heat from the fixing film 112 in the vicinity of the nip N. The thermistor 115 detects the change in the temperature of the fixing film 112 from which heat is drawn by the printing material. The control unit 1000 controls electric power to be supplied to the heating resistor 1131 of the heater 113 so that the detected temperature reaches a target temperature. When a printing material having a high coverage rate pattern, such as a graphic image, or a printing material with high moisture content is subjected to a fixing process, the printing material draws more heat from the fixing film 112 in the vicinity of the nip N, so that the temperature of the fixing film 112 drops greatly. If the time until the decrease in the temperature of the fixing film 112 is detected by the thermistor 115 is long, the timing to increase the amount of heat generated from the heater 113 is also delayed, so that the temperature of the fixing film 112 decreases continuously. When the temperature of the fixing film 112 is thus lowered, a fixing defect can occur. To cope with it, there is a method for constantly setting the target temperature of the heater 113 high in advance so as to satisfy the fixing performance even if the temperature of the fixing film 112 drops greatly when a pattern with high coverage rate or a printing material with high moisture content is subjected to fixing processing. However, when the target temperature of the temperature detecting member 115 is always set high, excessive electric power is supplied to the heater 113 even for a printing material on which an image with a low-coverage rate, which needs less heat, is formed, resulting in a decrease in power saving function.
To address this problem, the present embodiment includes not only a heat transfer path from the fixing film 112 to the thermistor 115 via both of the two components, the heater 113 and the heat conducting member 140, but also a path via only the heat conducting member 140. This produces the effect that a change in the temperature of the fixing film 112 can be detected via the heat conducting member 140 by the thermistor 115 even if the thermistor 115 is not in direct-contact with the fixing film 112.
The following is a verification whether a change in the temperature of the fixing film 112 can be detected with high responsiveness by the thermistor 115 in the case where the coverage rate of the printing material is varied and the case where printing materials having different moisture contents are used in the present embodiment. Fixing temperatures of the temperature sensor 115 necessary for fixing processing under various conditions were calculated. The fact that it is necessary to increase the fixing temperature means that the timing when the amount of heat generated from the heater 113 is delayed from the timing when the temperature of the fixing film 112 decreases. In other word, the responsiveness of detecting the decrease in the temperature of the fixing film 112 with the temperature sensor 115 is low.
The present embodiment is compared with Comparative Example 3 in which the protrusion amount h is −100 μm and Comparative Example 4 in which the protrusion amount h is 0 μm. Furthermore, evaluation was conducted under the following three conditions to confirm that the high responsiveness of the thermistor 115 for the fixing film 112 does not depend on the nip width between the extending portion 140b of the heat conducting member 140 and the fixing film 112, that is, the contact state. The first condition is that the pressing force at the nip N is low and the roller hardness is high, so that the width of the nip N is decreased (pressing force: 13 kgf, roller hardness: 52°, nip width: 5 mm). The second is a condition under with the width of the nip N is increased (pressing force: 15 kgf, roller hardness: 48°, nip width: 7 mm). The third is a condition under which the width of the nip N is an intermediate value of the values under the above two conditions (pressing force: 14 kgf, roller hardness: 50°, nip width: 6 mm).
For print patterns for evaluation, a text pattern with a low toner coverage rate and a solid black pattern of printing toner on the entire surface were used. For the moisture content of the printing material, sample 1 which is a printing material immediately after being unpacked and sample 2 left for about one week after being unpacked. Since the experiment was conducted in a high-temperature high-humidity environment at a temperature of 30° C. and a humidity of 80%, the moisture content of sample 1 was about 4%, and the moisture content of sample 2 was about 8%.
In Comparative Example 3 in which the protrusion amount h is set at −100 μm, a fixing temperature necessary for fixing the solid black pattern needed to be 15° C. higher than a fixing temperature necessary for fixing the text pattern, with the other conditions unchanged. A fixing temperature necessary for fixing toner to sample 2 needed to be 10° C. higher than a fixing temperature necessary for fixing toner to sample 1, with the other condition unchanged. Furthermore, when the width of the nip N is decreased by 1 mm, there was the tendency for the necessary fixing temperature to be increased by 5° C., with the other conditions unchanged. Consequently, in Comparative Example 3, a fixing temperature for satisfying the fixing performance, that is, a target temperature in control, was 210° C. regardless of the print pattern, the moisture content of the printing material, and the width of the nip N.
In Comparative Example 4 in which the protrusion amount h is set at 0 μm, the same results as those of Comparative Example 3 were given when the width of the nip N is 5 mm and 6 mm. Also when the width of the nip N is 7 mm, that is, the width of the nip N is increased by 1 mm from 5 mm and 6 mm, a necessary fixing temperature could be decreased by 5° C., with the other conditions unchanged, as in Comparative Example 3. However, in the case where the width of the nip N is 7 mm, a fixing temperature necessary for fixing the solid black patter needed to be higher than a fixing temperature necessary for fixing the text pattern, with the other conditions unchanged. Furthermore, a fixing temperature necessary for fixing toner to sample 2 needed to be 5° C. higher than a fixing temperature necessary for fixing toner to sample 1, with the other condition unchanged. In other word, a necessary fixing temperature was lower than that in Comparative Example 3 only when the width of the nip N is 7 mm. This seems to be because the width of the heater 113 is smaller than the width of the nip N, the extending portion 140b of the heat conducting member 140 in the vicinity of the heater 113 and the inner surface of the fixing film 112 are brought into contact by the pressing force at the nip N, causing stable heat transfer. Thus, in Comparative Examples 3 and 4, a fixing temperature that satisfies the fixing performance, that is, a target temperature in control, was 210° C. regardless of the target print pattern, the moisture content of the printing material, and the width of the nip N.
In the present embodiment, a fixing temperature necessary for fixing a solid black pattern needed to be 5° C. higher than a fixing temperature necessary for fixing a text pattern, with the other conditions unchanged.
Furthermore, a fixing temperature necessary for fixing toner to sample 2 needed to be 5° C. higher than a fixing temperature necessary for fixing toner to sample 1, with the other conditions unchanged. With the configuration of the present embodiment, there is no change in the fixing temperature required at the three widths of the nip N in the experiment, and s fixing temperature that satisfies the fixing performance, that is, a target temperature in control, was 195° C., regardless of the width of the nip N, the print pattern, and the moisture content of the printing material. In other words, the configuration of the present embodiment allows the target temperature of the temperature sensor 115 in fixing processing to be lower than those in Comparative Examples 3 and 4. This may be due to the fact that the contact between the extending portion 140b and the fixing film 112 is kept even when the fixing film 112 rotates, so that the rotation track fluctuates. As a result, a decrease in the temperature of the fixing film 112 is detected by the thermistor 115 with high responsiveness, and the amount of heat generated from the heater 113 can be increased.
As described above, the present embodiment offers the advantage that a change in the temperature of the fixing film 112 can be detected with higher responsiveness than the first embodiment by the thermistor 115 via the heat conducting member 140.
In the present embodiment, the extending portion 140b of the heat conducting member 140 is disposed only on the upstream side of the heater 112 in the rotational direction of the fixing film 112. However, this is given for mere illustration. The extending portion 140b of the heat conducting member 140 may be disposed only downstream from the heater 112 in the rotational direction of the fixing film 112.
Next, a modification of the present embodiment will be described.
In the configuration of the modification, the contact area between the heat conducting member 140 and the fixing film 112 is larger than the contact area in the fifth embodiment. Therefore, a change in the temperature of the fixing film 112 can be detected by the thermistor 115 via the heat conducting member 140 with higher responsiveness.
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. 2017-128001, filed Jun. 29, 2017, and No. 2017-128002, filed Jun. 29, 2017, which are hereby incorporated by reference herein in their entirety.
Number | Date | Country | Kind |
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JP2017-128001 | Jun 2017 | JP | national |
JP2017-128002 | Jun 2017 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2018/015405 | 4/12/2018 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2019/003575 | 1/3/2019 | WO | A |
Number | Name | Date | Kind |
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20100329753 | Pawlik | Dec 2010 | A1 |
20140003847 | Nishida | Jan 2014 | A1 |
20150139707 | Suzumi | May 2015 | A1 |
20170031284 | Ogawa | Feb 2017 | A1 |
20180373186 | Sato | Dec 2018 | A1 |
20190302664 | Morihara | Oct 2019 | A1 |
Number | Date | Country |
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1995646 | Nov 2008 | EP |
2003-257592 | Sep 2003 | JP |
2010-091665 | Apr 2010 | JP |
2016-071284 | May 2016 | JP |
Number | Date | Country | |
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20200192259 A1 | Jun 2020 | US |