The present invention relates to an image heating apparatus, which is used as a fixing device mountable in an image forming apparatus such as an electrophotographic copying machine, an electrophotographic printer, and the like.
There has been known a fixing apparatus of the film heating type, which is mountable in an electrophotographic copying machine, an electrophotographic printer, and the like. A fixing apparatus of this type is made up of a heater, a fixation film, a pressure roller, etc. The heater has a ceramic substrate and a heat generating resistor formed on the substrate. The fixation film is placed in contact with the heater. The pressure roller is pressed against the heater, with the placement of the fixation film between itself and heater, forming thereby a nip. A sheet of recording medium on which an unfixed toner image is present is conveyed through the nip of the fixing apparatus while remaining sandwiched by the fixation film and pressure roller, whereby the toner image on the sheet of recording medium becomes fixed to the sheet of recording medium.
A fixing apparatus such as the above described one which employs a heater has a power supply circuit for supplying the heater of the fixing apparatus with electric power. Thus, if the power supply circuit becomes abnormal in operation, it sometimes suffers from the so-called “heater cracking attributable to runaway power supply circuit”), that is, the phenomenon that the heater substrate (which hereafter may be referred to simply as substrate) cracks due to malfunction of power supply circuit for heater). Thus, it is desired that a fixing device of the above-described type is designed so that it can prevent its heater substrate from cracking even if its power supplying circuit for the heater malfunctions. More concretely, if a triac, a relay, and/or the like, which is a part of the above-mentioned power supply circuit malfunctions, the power supply circuit sometimes fails to control its primary current, allowing thereby the primary current to be supplied to the heater. In such a case, the heater abnormally increases in temperature, subjecting thereby its substrate to thermal stress. If this thermal stress is large, the heater substrate sometimes cracks, making the heater unusable. Further, as the heater excessively increases in temperature, a heater holder which holds the heater may melt, which in turn may subject the heater to mechanical stress large enough to cause the substrate to crack. As the substrate of the heater cracks, the heater becomes useless.
One of the methods for preventing a fixing device of the above described type from suffering from the “heater cracking attributable to runaway power supply circuit”, is to design a fixing device so that its thermal fuse, thermal switch, and/or the like component interrupts the primary current before the heater substrate is made to crack by the thermal and/or mechanical stress caused by the abnormal temperature increase of the heater, which is attributable to the flowing of the primary current of the power supply circuit into the heater. In the case of this method, it is required that the heater substrate can withstand the thermal and/or mechanical stress longer than the length of time it takes for a current interrupting member such as the thermal fuse, a thermal switch, and/or the like to react.
There is disclosed in Japanese Laid-open Patent Application 2007-121955 a technology which keeps the heater substrate as uniform as possible in temperature in order to extend the length of time it takes for the heater to crack after the power supply circuit goes out of control. More concretely, according to this patent application, a heat radiating member, which is proportional in thermal capacity to the amount of heat generation of the heat generating member on the “front” surface of the substrate, is attached to a specific portion of the back surface of the heater substrate, more specifically, the portion of the back surface of the heater substrate, which corresponds in position to the portion of the heater, which is higher in the amount of heat generation than the rest, in order to keep the heater substrate as uniform in temperature as possible.
However, the examination of a fixing device similar to the one disclosed in the abovementioned patent application revealed that it is likely that as its heater went out of control, cracking occurs to the portion of the substrate, which is in contact with a current interrupting member such as a fuse.
One of the causes for the above described problem is as follows: The current interrupting member is relatively large in thermal capacity. Therefore, the portion of the substrate, which is in contact with the current interrupting member, is robbed of heater by the current interrupting member, and therefore, reduces in temperature quicker than the rest of the substrate. Consequently, the substrate becomes nonuniform in temperature, which in turn is likely to subject the substrate to thermal stress. Further, because the current interrupting member is in contact with the substrate, the substrate is also subject to the mechanical stress attributable to the current interrupting member (substrate is pressed by current interrupting member), adding to the amount of the stress to which the substrate is subjected.
There are some cases in which a current interrupting member is attached to the substrate with the placement of a spacer made of resin, between the current interrupting member and substrate. In such cases, the spacer made of resin may melt, and therefore, the current interrupting member may come into contact with the substrate, which in turn may cause the substrate to crack as described above. Further, there are some cases in which a current interrupting member is improperly attached to the substrate due to the errors which might occur during the assembly of the heater. More concretely, if a current interrupting member is fixed to the heater substrate in such a manner that it is tilted relative to the substrate, it may come into contact with the substrate. That is, if a current interrupting member such as the thermal switch, and/or the like is tilted relative to the substrate, the end of the hard metallic member of the current interrupting member, may contact the substrate, causing the mechanical stress attributable to the current interrupting member to concentrate on the point of contact between the current interrupting member and substrate, subjecting therefore the substrate to a very large amount of force. Thus, it is more likely for the substrate to crack at the point of the substrate, which corresponds in position to the current interrupting member, as the power supply circuit goes out of control.
Further, in the case of some fixing apparatuses of the film heating type, their heater holder is provided with through hole(s), and the current interrupting member is placed in the through hole of the heater holder in such a manner that it is placed in contact with the heater substrate. In other words, the hole has to be made through the heater holder for the attachment of the current interrupting member to the heater substrate. Thus, the portions of the heater holder, which have the hole for the current interrupting member, is less in mechanical strength. While the heater is normal in operation, the heater holder can satisfactorily hold the current interrupting member. However, as the heater goes out of control and causes the heater holder to soften (or melt), the portion of the heater holder, which has the hole for the current interrupting member, fails to support the current interrupting member, allowing the current interrupting member to sink into the heater holder, allowing thereby the current interrupting member to directly come into contact with the heater substrate. In other words, the heater (substrate) is subjected to an additional stress, making it likely for the heater (substrate) to crack.
In recent years, it has come to be required that an electrophotographic copying machine, an electrophotographic printer, and the like are reduced in the FPOT (First Page Out Time; length of time required to output first print), and increased in PPM (Pages Per Minutes; number of prints which can be output per minute). In order to meet such a requirement, it is necessary to supply the heater of a fixing apparatus with a substantially larger amount of electric power than that by which a conventional fixing apparatus is supplied with electric power. Because of the circumstance described above, there is desired a fixing apparatus which can more effectively prevent the problem that as its power supply circuit goes out of control, its heater cracks, than a fixing apparatus in accordance with the prior art.
The object of the present invention is to provide an image heating apparatus which can prevent its heat generating member from cracking when the heat generating member excessively increases in temperature.
According to an aspect of the present invention, there is provided an image heating apparatus for heating a toner image formed on a recording material, said image heating apparatus comprising a heater including a substrate and a heat generating resistor thereon for generating heat for heating the toner image, by electric power supply; an electric power shut-off member operable in response to an abnormality temperature rise of said heater to shut off the electric power supply; and a heat conduction member having a thermal conductivity, in a direction of a thickness of said substrate, higher than that of said substrate, wherein a contact area between said heat conduction member and said substrate is larger than a contact area between said heat conduction member and said electric power shut-off member.
According to another aspect of the present invention, there is provided an image heating apparatus for heating a toner image formed on a recording material, said image heating apparatus comprising a heater including a substrate and a heat generating resistor thereon for generating heat for heating the toner image, by electric power supply; an electric power shut-off member operable in response to an abnormality temperature rise of said heater to shut off the electric power supply, said electric power shut-off member including a cylindrical portion, and a heat conduction member having a thermal conductivity, in a direction of a thickness of said substrate, higher than that of said substrate, wherein a cylindrical surface of the cylindrical portion of said electric power shut-off member contacts a flat surface portion of said heat conduction member, and said heat conduction member is in surface contact with said substrate.
These and other objects, features, and advantages of the present invention will become more apparent upon consideration of the following description of the preferred embodiments of the present invention, taken in conjunction with the accompanying drawings.
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Hereinafter, some the preferred embodiments of the present invention are described in detail.
The image forming apparatus in this embodiment has: an image forming portion A, in which an unfixed toner image is formed on a sheet P of recording medium; a fixing portion C (which hereafter may be referred to as fixing device (image heating device)) C, which fixes the unfixed toner image on the sheet P to the sheet P; etc.
In the image forming portion A, a referential code 7 stands for a process cartridge, which is made up of an electrophotographic photosensitive member (which hereafter may be referred to simply as photosensitive drum) 1, a charge roller (charging means) 2, a developing device (developing means) 4, a cleaning blade (cleaning means) 6, and a cartridge in which the preceding components are integrally disposed. The photosensitive drum 1 is an image bearing member, and is in the form of a drum. The process cartridge 7 is removably installable in the main assembly B of the image forming apparatus, that is, the image forming apparatus minus the process cartridge 7.
The image forming apparatus in this embodiment is structured so that its photosensitive drum 1 is rotated in the direction indicated by an arrow mark at a preset peripheral velocity in response to a print command issued by an external apparatus such as a host computer, a terminal device or the like on a network. As the photosensitive drum 1 is rotated, its peripheral surface is charged to preset polarity and a preset potential level by the charge roller 2. The uniformly charged portion of the peripheral surface of the photosensitive drum 1 is scanned (exposed to) a beam of laser light outputted by a laser scanner unit (exposing means) 3, while being modulated (turned on or off) according to the information of the image to be formed, which is outputted by the external apparatus. Consequently, an electrostatic latent image, which reflects the information of the image to be formed, is formed on the peripheral surface of the photosensitive drum 1.
This electrostatic image is developed into a visible image, that is, an image formed of toner (toner image) by the development roller 4a of the developing device 4 which uses toner. There are various developing methods, for example, jumping developing method, two-component developing method, FEED developing method, etc., which can be used by the developing device 4. These methods are likely to be used in a combination of image exposure and reversal development.
While the toner image is formed, multiple sheets P of recording medium stored in layers in a sheet feeder cassette 13 are fed one by one into the main assembly B of the image forming apparatus, by the rotation of the sheet feeder roller 9, and then, are sent to a pair of registration rollers 10 through the first sheet passage 11. Then, each sheet P of recording medium is conveyed, with a preset sheet conveyance timing, by the pair of registration rollers 10 through the second sheet passage 12, to the transfer nip Tn, which is the area of contact between the peripheral surface of the photosensitive drum 1 and the peripheral surface of the transfer roller 5.
Then, the sheet P of recording medium is conveyed through the transfer nip Tn while remaining pinched by the peripheral surface of the photosensitive drum 1 and the peripheral surface of the transfer roller 5. During the conveyance of the sheet P through the transfer nip Tn, a transfer bias which is opposite in polarity to the toner, is applied to the transfer roller 5. Thus, the toner image on the peripheral surface of the photosensitive drum 1 is electrostatically transferred onto the sheet P in the transfer nip Tn; the toner image is borne by the sheet P.
The sheet P of recording medium, on which the unfixed toner image is present, is discharged from the transfer nip Tn while being separated from the peripheral surface of the photosensitive drum 1. Then, the sheet P is introduced into the fixation nip N of the fixing device C, through the third sheet passage 14, and is conveyed through the third sheet passage 14. While the sheet P is conveyed through the fixation nip N, the unfixed toner image on the sheet P is fixed to the sheet P. Then, the sheet P is conveyed out of the fixing device C. Thereafter, the sheet P is conveyed to a pair of discharge rollers 8 through the fourth sheet passage 15. Then, the pair of discharge rollers 8 convey further the sheet P onto the delivery tray 16 of the apparatus main assembly B.
After the separation of the sheet P of recording medium from the peripheral surface of the photosensitive drum 1, the toner and the like contaminants remaining on the peripheral surface of the photosensitive drum 1 are removed by the cleaning blade 6 to clean the peripheral surface of the photosensitive drum 1, so that the peripheral surface of the photosensitive drum 1 can be used for the following image formation.
In the following description of the embodiments of the present invention, the lengthwise direction of the fixing device C and the structural components thereof means the direction which is parallel to the surface of a sheet of recording medium being conveyed through the fixing device C, and perpendicular to the recording medium conveyance direction of the fixing device C. The widthwise direction of the fixing device C and the structural components thereof means the direction which is parallel to the surface of a sheet of recording medium being conveyed through the fixing device C, and also, to the recording medium conveyance direction of the fixing device C. The lengthwise dimension of the fixing device C and the structural components thereof means their dimension in terms of the lengthwise direction. The widthwise dimension of the fixing device C and the structural components thereof means their dimension in terms of the widthwise direction.
The fixing device C in this embodiment has a flexible, heat-resistant, and cylindrical fixation film (fixing member) 201, a pressure roller (pressure applying member) 202, the ceramic heater 203, a heater holder (heater supporting member) 204, a metallic stay (rigid member) 211, etc. The fixation film 201, pressure roller 202, ceramic heater 203 (which hereafter may be referred to simply as heater), heater holder 204, and metallic stay 211 are such members of the fixing device C that their lengthwise direction coincides with the lengthwise direction of the fixing device C. The heater 203 is 270 mm and 6 mm in the lengthwise and widthwise dimensions, respectively. The fixation film 201 is 230 mm in the lengthwise dimension. The lengthwise dimension of the elastic layer 202b (which will be described later) of the pressure roller 202 is 220 mm.
The heater holder 204 is formed of highly heat-resistant resinous substance such as PPS (polyphenylenesulfide), LCP (liquid crystal polymer), or the like. It is in the form of such a trough that is roughly semicircular in cross section. The heater holder 204 has a groove 204a which is in the downwardly facing surface of the heater holder 204. The groove 204a is centrally positioned in terms of the widthwise direction of the heater holder 204, and extends in the lengthwise direction of the heater holder 204. The heater 203 is held by the heater holder 204 by being fitted in this groove 204a of the heater holder 204. Further, the heater holder 204 is provided with a pair of film guiding surfaces 204b, which are at the widthwise ends of the heater holder 204, one for one, and by which the fixation film 202 is guided in such a manner that the fixation film 202 remains in the proper form while the fixation film 202 is circularly moved.
The metallic stay 211 is a rigid member. It is formed of a metallic substance which can provide the metallic stay 211 with a substantial amount of rigidity. It is shaped so that its cross section at a plane parallel to the widthwise direction is roughly in the form of a letter U, and also, so that its width is less than that of the heater holder 204. This metallic stay 211 is positioned above the heater holder 204 in such an attitude that its open side faces downward, and also, that its center line in terms of the widthwise direction coincides with the centerline of the heater holder 204.
The fixation film 201 is loosely fitted around the heater holder 204, to which the metallic stay 211 is attached. The fixation film 201 in this embodiment is made up of a cylindrical substrative layer (unshown) and a surface layer (parting layer) formed on the outward surface of the cylindrical substrative layer. The material for the substrative layer is a resinous substance such as thin polyimide, PEEK, or the like, or metallic substance such as SUS, nickel, or the like. The material for the surface layer is a fluorinated resin or the like which is excellent in parting properties.
The thermal capacity of the fixation film 201 is extremely small compared to that of a fixation roller employed by a conventional fixing device of the so-called heat roller type. Therefore, as electric power is supplied to the heater 203, the fixation nip N (which will be described later) of the fixing device C in this embodiment increases in temperature substantially quicker than that of a fixing device which employs a fixation roller. That is, the fixing device C in this embodiment can start up virtually instantly, that is, with virtually no waiting time; it becomes ready for image fixation very quickly.
Referring to
The substrate 203a in this embodiment is a piece of 1 mm thick aluminum plate (20 W/mK in thermal conductivity). The aforementioned two strips 203b of heat generating resistor are formed on the surface of the substrate 203a, by applying Ag/Pd (silver-palladium) paste in two strips in the lengthwise direction of the substrate 203a.
Further, the heater 203 is provided with a pair of power supply electrodes 203c, which are located at the lengthwise ends of the surface of the substrate 203a, being placed in contact with the two strips 203b of heat generating resistors, one for one. The power supply electrodes 203c are formed by screen-printing or the like method. The heater 203 is also provided with an electrically conductive portion 203d, which is at one of the lengthwise ends of the substrate 203a, being in contact with the two strips 203b of heat generating resistor. The electrically conductive portion 203d is formed of silver or the like substance, by screen-printing or the like method.
Regarding the method for forming the two power supply electrodes 203c and the electrically conductive portion 203d, the Ag paste was coated on one of the lengthwise ends of the surface of the substrate 203a, and fired, to form the two power supply electrodes 203c, whereas the Ag paste was coated on the other lengthwise end of the surface of the substrate 203a, and fired to form the electrically conductive portion 203d. The above described two strips 203b of heat generating resistor are in serial connection to the electrically conductive portion 203d. The measured overall electrical resistance of the combination of the serially connected two strips 203b of heat generating resistor was 18Ω.
Further, the heater 203 is provided with a glass coat (protective layer) 203e formed on the surface of the substrate 203a in such a manner that the glass coat 203e covers the two strips of heat generating resistor 203b, a part of the two power supply electrodes 203c, and electrically conductive portion 203d. Not only does this glass coat 203e protect the electrically conductive portion 203d from being damaged by the friction between the electrically conductive layer 203d and the inward surface of the fixation film 201, but also, minimize the friction between the surface of the substrate 203a and the inward surface of the fixation film 201 to ensure that the fixation film 201 is enabled to smoothly slide on the substrate 203a.
The pressure roller 202 has a metallic core 202a formed of iron, aluminum, or the like metallic substance. It has also an elastic layer 202b formed of silicone rubber, silicone sponge, or the like, on the peripheral surface of the metallic core 202a in a manner to cover the entirety of the peripheral surface of the metallic core 202a, except for the lengthwise end portions of the metallic core 202a, which function as the axle portion (unshown) of the pressure roller 202. The pressure roller 202 has also a parting layer 202c which is formed of fluorinated resin or the like, and covers the entirety of the outward surface of the elastic layer 202b.
The pressure roller 202 is rotatably supported by the frame (unshown) of the fixing device C. More specifically, the lengthwise end portions of the metallic core 202a of the pressure roller 202 are rotatably supported by a pair of bearings, with which the lateral plates of the frame of the fixing device C are provided one for one. The aforementioned heater holder 204 is above the pressure roller 202, and is positioned so that the peripheral surface of the pressure roller 202 opposes the outward surface of the fixation film 201. Further, the heater holder 204 is supported by its lengthwise end portions, by the abovementioned lateral plates (end plates in terms of lengthwise direction) of the frame of the fixing device C, in such a manner that the heater holder 204 is movable in the radius direction of the pressure roller 202.
The metallic stay 211 is placed on the upwardly facing portion of the top surface of the heater holder 204, and is kept under the preset amount of pressure generated in the vertical direction, that is, the direction perpendicular to the generatric of the fixation film 201, by a pair of pressure applying members (unshown) such as compression springs. This metallic stay 211 keeps the outward surface of the fixation film 201 pressed upon the peripheral surface of the pressure roller 202 through the heater holder 204. Therefore, the elastic layer 202b of the pressure roller 202 remains compressed, providing thereby the fixing device C with the fixation nip N, which is necessary for the fixation of an unfixed toner image, and has a preset width in terms of the widthwise direction, between the peripheral surface of the pressure roller 202 and the outward surface of the fixation film 201.
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The heat conduction layer 207 is 15 mm in length and 5 mm in width. Referring to
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The thermal fuse 206 is such a component that senses the abnormality (excessiveness) of the heat generation of the heater 203, and breaks the primary circuit of the power supply circuit PS (which will be described later) as the heater 203 excessively increases in temperature, that is, as the heater 203 generates an excessive amount of heat. Referring to
The metallic shell 206a of the thermal fuse 206 in this embodiment has a cylindrical portion. In terms of the lengthwise direction, the area of contact between the cylindrical portion of the thermal fuse 206 and the heat conduction layer 207 is roughly 10 mm. The width (diameter) of the cylindrical portion is roughly 4 mm.
The thermal fuse 206 may be attached to the heat conduction layer 207, with the placement of a layer of heat conducting grease (SC-102: product of Toray-Dow-Corning Co., Ltd., which is 2.4 t W/mK) in thermal conductivity) between itself and the heat conduction layer in order to prevent the problem that the thermal fuse 206 malfunctions due to its separation from the heat conduction layer 207.
The power supply circuit PS has the secondary circuit made up of the temperature controlling section 100, one of the thermistor contacts 205s, thermistor 205, other thermistor contact 205s, etc., which are serially connected.
The temperature control section 100 drives the triac 101 according to the information regarding the temperature detected by the thermistor 205 attached to the center of the substrate 203a in terms of the lengthwise direction, controlling thereby the amount of electric power to be supplied to the strips 203b of heat generating resistor of the heater 203 so that the temperature of the heater 203 is kept at a preset fixation level (target level).
The methods usable by the above described control section 100 to control the electric power supply to the strips 203b of heat generating resistor is a multistage power control, for example, the zero-crossing wave number control which turns on or off the triac 101 for every half of the power source wave pattern, phase control which controls the power supply in phase angle for every half of the waveform of the current supplied by the power supply circuit PS, and the like method.
The driving control section (unshown) begins to rotationally drive the motor (unshown) in response to a print start command. The rotation of the output shaft of this motor is transmitted to the gear (unshown) attached to one of the lengthwise ends of the shaft 202a of the pressure roller 202, whereby the pressure roller 202 is rotated in the direction indicated by an arrow mark at a preset peripheral velocity (process speed).
The rotation of the pressure roller 202 is transmitted to the surface of the fixation film 201 by the friction which occurs between the peripheral surface of the pressure roller 202 and the outward surface of the fixation film 201 in the fixation nip N. Thus, the fixation film 201 rotates (circularly moves) in the direction indicated by an arrow mark by the rotation of the pressure roller 202, with the inward surface of the fixation film 201 remaining in contact with the glass coat 203e of the ceramic heater 203 and the edge portions of the heater holder 204 in terms of the widthwise direction.
The temperature control section 100 turns on the triac 101 in response to the print start signal. Thus, electric current begins to flow to the strips 203b of heat generating resistor of the heater 203 from the AC power source 102 through the power supply terminal 203c. Thus, the strips 203b of heat generating resistor quickly increases in temperature, causing the heater 203 to heat the fixation film 201 from the inward side of the fixation film 201.
The temperature of the heater 203 (center portion) is detected by the thermistor 205. The temperature control section 100 receives the information about the temperature of the heater 203 from the thermistor 205, and controls the triac 101 based on the information about the temperature of the heater 203, so that the temperature of the heater 203 remains at the preset fixation level (target level).
While the pressure roller 202 is rotating and the temperature of the heater 203 is remaining at the preset fixation level, a sheet P of recording medium, on which a toner image T (unfixed image) is present, is introduced into, and conveyed through, the fixation nip N while being guided by the entrance guide 212, with the toner bearing surface of the sheet P facing upward. While the sheet P is conveyed through the fixation nip N, it remains sandwiched by the outward surface of the fixation film 201 and the peripheral surface of the pressure roller 202, receiving thereby heat from the fixation film 201. Further, while the sheet P is conveyed through the fixation nip N, it is subjected to the internal pressure of the fixation nip N while receiving the heat from the fixation film 201. That is, the toner image T on the sheet P is pressed by the pressure roller 202 while being melted by the heat from the fixation film 201. Consequently, the toner image T becomes fixed to the sheet P. After the fixation of the toner image T to the sheet P, the sheet P is conveyed out of the fixation nip N while being separated from the outward surface of the fixation film 201.
The fixing device C in this embodiment was subjected to a runaway test, that is, a test for finding out how the fixing device C behave as the heater 203 goes out of control.
It is when the fixing device C is continuously supplied with the largest amount of electric power which can be supplied by the image forming apparatus that the heater 203 is subjected to the largest amount of thermal stress.
Thus, it is assumed that not only the triac 101 of the primary circuit of the power supply circuit PS shorted, but also, the relay shorted at the same time. That is, a power supply circuit (PS) having a shorted triac and a shorted relay was constructed, and is connected to an unshown outlet. Since the resistance value of the strips 203b of heat generating resistor is 18Ω, the heater 203 will end up receiving 800 W of electric power.
This primary circuit was directly connected to the heater 203 of the fixing device C of the image forming apparatus. The length of time it took for the heater 203 (substrate 203a) to crack after the connection of the heater 203 to the power supply circuit PS was measured.
The thermal fuse 206 was kept disconnected from the primary circuit. Further, a low voltage power source is prepared to apply a small amount (several voltages) of voltage to the thermal fuse 206 to monitor the amount of the current which flows through the thermal fuse 206. As the thermal fuse 206 opens, the current from the low voltage power source is interrupted. Thus, by measuring the length of time it takes for the current flowing through the thermal fuse 206 to be interrupted while supplying the primary circuit with the electric power from the commercial power source, and the thermal fuse 206 with the electric power from the low voltage power source, it is possible to measure the length of time it takes for the thermal fuse 206 to open, as well.
Thus, it is possible to find out whether or not the thermal fuse 206 opens before the substrate 203a cracks as the heater 203 goes out of control due to the malfunctioning of the primary circuit while the fixing device C is in operation.
In the runway test for testing how the heater 203 is controlled as the power supply circuit PS goes out of control, the fixing device C in this embodiment, and a comparative fixing device, were actually tested. The comparative fixing device was not provided with the heat conduction layer 207 which is to be formed on the back surface of the substrate 203a by the coating the back surface with Ag paste and firing the Ag paste. In other words, the comparative fixing device was structured so that the thermal fuse 206 was attached to the back surface of the substrate 203a, with the presence of only the thermally conductive grease (without heat conduction layer 207). Otherwise, the comparative fixing device was the same in structure as the fixing device C in this embodiment.
When the fixing device C in this embodiment was subjected to the above-described runaway test (heater control) using the above described method, the thermal fuse 206 melted in 6.3 seconds, and it took 10.3 second for the heater 203 to crack. Thus, it is evident that there was a margin of 4 seconds between the opening of the thermal fuse 206 and the cracking of the heater 203.
The point of the substrate 203a, at which the substrate 203a cracked, corresponded in position to the thermistor 205 (point of contact between substrate 203a and thermistor 205). The reason for this correspondence seems to be as follows. That is, the portion of the substrate 203a, which is most likely to crack, that is, the portion of the substrate 203a, to which the thermal fuse 206 is attached, became less likely to crack. Consequently, the point of contact between the thermistor 205 and substrate 203a, that is, the portion of the substrate 203a, which is most likely to crack after the portion of the substrate 203a to which the thermal fuse 206 is attached, became most likely to crack.
The comparative fixing device was subjected to the same runaway test as the one to which the fixing device C in this embodiment was subjected. The length of time it took for the thermal fuse 206 to open was 6.3 seconds, which is the same as the fixing device C in this embodiment. However, the length of time it took for the substrate 203a of the heater 203 to crack was 6.0 seconds. That is, the aforementioned margin was smaller. In addition, the point of the substrate 203a, at which the substrate 203a cracked, was the point of contact between the thermal fuse 206 and substrate 203a. This seems to have occurred for the following reason. That is, the point of the substrate 203a, with which the thermal fuse 206, is in contact, reduced in temperature more than the other portion of the substrate 203a. This difference in temperature between the point of the substrate 203a, which is in contact with the thermal fuse 206, and the rest of the substrate 203a, generated thermal stress in the substrate 203a, which made the substrate 203a more likely to crack at the point of contact between the substrate 203a and thermal fuse 206.
In particular, the thermal fuse 206 in this embodiment has the cylindrical portion, which is in contact with the flat portion of the substrate 203a, by its peripheral surface, as described above. That is, the area of contact between the thermal fuse 206 and substrate 203a is linear or a point (thermal fuse 206 is tilted relative to substrate 203a). In other words, the heat of the substrate 203a is robbed by the thermal fuse 206 through the very small area of the substrate 203a, that is, the area (point) of contact between the thermal fuse 206 and substrate 203a. Therefore, the area of the substrate 203a, which is in contact with the thermal fuse 206, is likely to reduce in temperature more than the rest of the substrate 203a.
During the runaway test, the difference in temperature between the portion (point) of the substrate 203a, which corresponds in position to the thermal fuse 206, and the portion (point) of the substrate 203a, which corresponds in position to the strips 203b of heat generating resistor, was measured. More concretely, a pair of thermocouples were pasted to the portions of the surface of the substrate 203a of the heater 203, which is in the recording medium conveyance passage and correspond in position to the thermal fuse 206 and strips 203b of heat generating resistor. Then, the difference in temperature between the portion of the substrate 203a, which corresponds in position to the thermal fuse 206, and the portion of the substrate 203a, which corresponds in position to the strips 203b of heat generating resistor, was measured. In the case of the fixing device C in this embodiment, the difference was 27° C. even 10 seconds after the starting of the runaway test. In comparison, in the case of the comparative fixing device, it became 66° C. six seconds after the starting of the runaway test.
To roughly calculate the amount of the thermal stress to which the substrate 203a is subjected,
σ=EαΔT
(σ: thermal stress, E: Young's modulus, α: coefficient of linear expansion, ΔT: temperature difference).
Since alumina is 3.5×105 in Young's modulus and 7.8×10−6 (/° C.) in coefficient of linear expansion, the amount of thermal stress to which the substrate 203a is subjected 10 seconds after the starting of the runaway test is 73.7 MPa/mm2.
In comparison, the amount of thermal stress to which the substrate 203a of the comparative fixing device is subjected 10 seconds after the starting of the runaway test, which is obtainable with the use of the same calculating method used for the fixing device C in this embodiment, is roughly 180 MPa/mm2. Even though the tensile strength of aluminum is roughly 255 MPa/mm2, the substrate 203a is also subjected to the mechanical stress from the pressure roller 202, etc. Therefore, it has been empirically known that the substrate 203a of the heater 203 is likely to crack as the amount of thermal stress to which the substrate 203a is subjected increase to a value in a range of 150-200 MPa/mm2.
In the case of the fixing device C in this embodiment, its thermal fuse 206 is attached to the heat conduction layer 207 which is on the back surface of the substrate 203a. Therefore, it is reasonable to think that the portion of the substrate 203a, which corresponds in position to the thermal fuse 206, that is, the portion of the substrate 203a, which is the largest in the amount of thermal stress, and also, the amount of mechanical stress, is smaller in the amount of stress than the same portions of the substrate 203a of the comparative fixing device. Therefore, it is also reasonable to think that the fixing device C (substrate 203a) in this embodiment lasts longer than the comparative fixing device. More specifically, in the case of the fixing device C in this embodiment, which is structured as described above, heat is robbed from the substrate 203a by the thermal fuse 206 through the heat conduction layer 207 as the heater 203 goes out of control. The area of contact between the heat conduction layer 207 and substrate 203a is larger than the area of contact between the thermal fuse 206 and heat conduction layer 207. Thus, the fixing device in this embodiment is greater in the area of the substrate 203a, through which heat is robbed from the substrate 203a by the thermal fuse 206, than the comparative fixing device. That is, in the case of the fixing device C in this embodiment, the area of the substrate 203a of the heater 203, from which heat is robbed by the thermal fuse 206, is larger (wider) than in the case of the comparative fixing device. Therefore, the substrate 203a in this embodiment is unlikely to locally reduce in temperature.
Also in the case of the comparative fixing device, the portion of the substrate 203a, which corresponds in position to the thermal fuse 206, is coated with thermally conductive grease. However, the thermal conductivity of the thermally conductive grease is lower than the alumina, which is the material for the substrate 203a. Therefore, the thermal conductive grease alone is insufficient to keep the substrate 203a virtually uniform in temperature. That is, in order to keep the substrate 203a virtually uniform in temperature, the thermally conductive layer 207, which is formed of a substance which is higher in thermal conductivity than the substrate 203a, is necessary.
As described above, in the case of the fixing device C in this embodiment, the heat conduction layer 207, which is greater in thermal conductivity is attached to the back surface of the substrate 203a of the heater 203, and the metallic shell 206a of the thermal fuse 206 is placed in contact with the heat conduction layer 207. Thus, the portion of the substrate 203a, which corresponds in position to the thermal fuse 206, is minimized in nonuniformity in terms of thermal stress, when the heater 203 abnormally increases in temperature. Therefore, it is longer in the length of time it takes for the substrate 203a to crack. That is, the thermal fuse 206 opens before the heater 203 cracks when the power supply circuit PS goes out of control. In other words, the fixing device C in this embodiment is unlikely to suffer from the problem that as the power supply circuit PS goes out of control, the heater 203 abnormally increases in temperature, and therefore, the substrate 203a of the heater 203 cracks.
Next, the fixing device C in another (second) embodiment of the present invention is described.
The fixing device C in this embodiment is structured so that the heat conduction layer 207 to be placed on the back surface of the substrate 203a can be minimized in size, and also, so that the thermally conductive grease is unnecessary. This structural arrangement also can provide a fixing device C which can prevent the problem that when the heater 203 is started up, the portion (point) of the substrate 203a, which corresponds in position to the thermal fuse 206, is reduced in temperature by the thermal capacity of the thermal fuse 206. It is also effective to prevent the problem that as the power supply circuit PS goes out of control, the substrate 203a of the heater 203 cracks.
In the case where the thermal fuse 206 is placed directly in contact with the back surface of the substrate 203a, there occurs a difference in temperature between the portion of the substrate 203a, to which the thermal fuse 206 is attached, and the rest of the substrate 203a, because of the thermal capacity of the thermal fuse 206 itself, while the heater 203 is started up, that is, while the heater 203 is increased in temperature to the fixation level, in particular, from the room temperature.
Referring to
The fixing device C in this embodiment is capable of preventing the portion of the substrate 203a, which is in contact with the thermal fuse 206 from becoming lower in temperature than the rest, and therefore, can prevent the problem that as the power supply circuit PS goes out of control, the substrate 203a of the heater 203 cracks.
Referring to
The metallic shell 206a of the thermal fuse 206 is likely to be cylindrical. Thus, it sometimes occurs that the thermal fuse 206 (metallic shell 206a) is disposed slightly tilted, and therefore, one of the end portions 206a1 of the metallic shell 206a is placed in contact with the back surface of the substrate 203a. In a case where one of the end portions 206a1 is placed in contact with the back surface of the substrate 203a, the substrate 203a is affected in temperature distribution only at the point of contact between the back surface of the substrate 203a and the end portion 206a1 of the metallic shell 206a, that is, across very small area of the substrate 203a. Therefore, in a case where the thermal fuse 206 is attached to the substrate 203a so that it is angled relative to the substrate 203a, the substrate 203a is likely to crack, which has been empirically known.
As for the means for prevent the problem that if the thermal fuse 206 is attached to the substrate 203a so that it is angled relative to the substrate 203a, the substrate 203a of the heater 203 is likely to crack as the power supply circuit PS goes out of control, it is effective to place the heat conduction layer 207 on the back surface of the substrate 203a in such a manner that the heat conduction layer 207 covers the point of contact between the thermal fuse 206 and the back surface of the substrate 203a.
When the heater 203 of the fixing device C, in this embodiment, which is in an image forming apparatus, was started up, the portion of the back surface of the substrate 203a, which corresponds in position to the thermal fuse 206, and the rest, were the same in temperature change. Further, even the first print was not less in image quality, such as glossiness, than a satisfactory print.
When the fixing device C in this embodiment was subjected to the runaway test similar to the one to which the fixing device C in the first embodiment was subjected, it took 7.2 seconds for the thermal fuse 206 to open, whereas it took 9.8 seconds for the heater 203 (substrate 203a) to crack. It is evident from the results of this test that there was sufficient amount of time for the thermal fuse 206 to prevent the heater 203 (substrate 203a) from cracking, should the power supply circuit PS go out of control.
In the above-described runaway test, a pair of K thermocouples were pasted to the portions of the surface of the substrate 203a of the heater 203, which is in the recording medium conveyance passage and correspond in position to the thermal fuse 206 and strips 203b of heat generating resistor, one for one. Then, the temperature of these portions were detected. The difference in temperature between the portion of the substrate 203a, which corresponds in position to the strips 203b of heat generating resistor, and the portion of the substrate 203a, which corresponds in position to the thermal fuse 206, was 28° C., and the amount of thermal stress was 76.4 MPa/mm2.
In the case of the comparative fixing device, the heat conduction layer 207 was not formed on the back surface of the substrate 203a (process of coating Ag paste on back surface of substrate 203a and firing it was not carried out), and the thermal fuse 206 was directly disposed on the substrate 203a, that is, without placing a layer of thermally conductive grease between the thermal fuse 206 and substrate 203a. In other words, the comparative fixing device is the same in structure as the fixing device C in this embodiment, except for the above-described difference. This comparative fixing device was subjected to the same runaway test as the one to which the fixing device C in this embodiment was subjected. It took 7.4 seconds for the thermal fuse 206 to open, where as it took 6.2 seconds for the heater 203 (substrate 203a) to crack. Further, the point at which the heater 203 (substrate 203a) cracked was the point of contact between one of the lengthwise end portion 206a1 of the metallic shell 206a of the thermal fuse 206.
6.0 seconds after starting the runaway test, the difference in temperature between the portion of the substrate 203a, which corresponds in position to the strips 203c of heat generating resistor, and the portion of the substrate 203a, which corresponds in position to the thermal fuse 206, was 65° C., and the amount of thermal stress was 177.4 MPa/mm2.
Also in the case of the comparative fixing device in this embodiment, unless the heat conduction layer 207 is provided, the portion of the substrate 203a, which is in contact with one of the lengthwise ends 206a1 of the metallic shell 206a of the thermal fuse 206, is subjected to a large amount of thermal stress, and also, the aforementioned mechanical stress. This seems to be the reason why the heater 203 (substrate 203a) cracked.
As described above, in the case of the fixing device C in this embodiment, two thermally conductive layer layers 207 are placed on the two separate areas of the back surface of the substrate 203a, one for one, and the lengthwise end portions 206a1 of the metallic shell 206a of the thermal fuse 206 are placed in contact with the two thermally conductive layers 207, one for one. Thus, the presence of these thermally conductive layers 207 can minimize in severity the phenomenon that as the heater 203 abnormally increases in temperature, the portion of the substrate 203a, which corresponds in position to the thermal fuse 206 becomes nonuniform in thermal stress. That is, the second embodiment also can provide the effects similar to those which can be provided by the first embodiment.
Next, another (third) embodiment of the present invention is described.
The fixing device C in this embodiment does not have the heat conduction layer 207 on the back surface of the substrate 203a. Instead, the back surface of the substrate 203a is provided with the aluminum plate 208, which can provide the same effects as those which can be provided by the thermally conductive layer 207. Otherwise, the fixing device C in this embodiment is the same in structure as the one in the fixing device C in the first embodiment.
Referring to
In the case of this embodiment, the thermal conductivity of the substrate 203a as a thermally conductive member, in terms of its thickness direction, is particularly important, because the thermal fuse 206 detects the temperature of the heater 203 through the aluminum plate 208. Thus, such a material as graphite plate that is anisotropic in thermal conductivity, that is, its thermal conductivity in its thickness direction is substantially smaller than that in its surface direction, is difficult to use as the material for the thermally conductive member in this embodiment, because the thermal conductivity of the graphite sheet in its thickness direction is smaller than the thermal conductivity of the substrate 203a which is formed of ceramic such as alumina.
Referring to
The fixing device C in this embodiment was subject to the same runaway test as the one to which the fixing device C in the first embodiment was subjected. The results of the test are as follows. The length of time it took for the thermal fuse 206 to open was 6.3 seconds, which is the same as the fixing device C in the first embodiment. However, the length of time it took for the heater 203 (substrate 203a) to crack was 13.2. In other words, this embodiment was more effective to prevent the heater 203 (substrate 203a) from cracking, that is, to extend the heater 203 in service life, than the first embodiment.
Aluminum which is the material for the aluminum plate 208, is lower in thermal conductivity than Ag which is the material for the heat conduction layer 207 in the first embodiment. However, the thickness of the aluminum plate 208 is roughly 0.3 mm, which is roughly 30 times the thickness of the Ag paste in the first embodiment, which is 10 μm. Therefore, it is greater in thermal conduction (transfer), being more effective to make the substrate 203a uniform in temperature, than the Ag paste. The portions of the surface of the substrate 203a, which are in the recording medium passage and correspond in position to the thermal fuse 206 and strips 203b of heat generating resistor, are measured in temperature by a couple of K thermocouples attached thereto, one for one. 13 seconds after the starting of the runaway test, the difference in temperature between the portions of the surfaces of the substrate 203a, which correspond in position to the strips 203c of heat generating resistor and thermal fuse 206, respectively, was 28° C., and the amount of thermal stress was 76.4 MPa/mm2.
Further, the aluminum plate 208 is rigid by itself. Therefore, even if the heater holder 204 melts, the aluminum plate 208 can prevent a part, or parts, of the heater 203 from buckling. Therefore, it seems to reasonable to think that this embodiment can further extend the fixing device C (heater 203) in service life.
As described above, in the case of the fixing device C in this embodiment, the metallic shell 206a of the thermal fuse 206 is placed in contact with the aluminum plate 208 which is placed on the back surface of the substrate 203a of the heater 203 and is greater in thermal capacity than the substrate 203a. Therefore, the aluminum plate 208 can minimize the problem that as the heater 203 abnormally increases in temperature, the portion of the substrate 203a, which corresponds in position to the thermal fuse 206 becomes nonuniform in thermal stress. In other words, this embodiment can provide the same effects as the first embodiment.
Next, another (fourth) embodiment of the present invention is described.
In the case of the fixing device C in this embodiment, the thermoswitch 209 was employed as a current interrupting member, in place of the thermal fuse 206. Otherwise, the fixing device C in this embodiment is the same in structure as the fixing device C in the first embodiment.
Referring to
Referring to
When the fixing device C in this embodiment was subjected to the same runaway test as the one to which the fixing device C in the first embodiment was subjected, it took 3.5 seconds for the thermoswitch 209 to turn itself off, where the length of time it took for the heater 203 (203a) to crack was 10.3 seconds, which was the same as the fixing device C in the first embodiment. It is evident from these results that the employment of the thermoswitch 209 can provide a substantial amount of margin in time between the point in time at which the thermoswitch 209 reacts and the point in time at which the heater 203 (substrate 203a) cracks.
As described above, in the case of the fixing device C in this embodiment, the heat sensing portion 209b of the thermoswitch 209 is placed in contact with the heat conduction layer 207 which is on the back surface of the substrate 203a of the heater holder 204 and is greater in thermal conductivity than the substrate 203a. Thus, the heat conduction layer 207 can minimize in severity the problem that as the heater 203 abnormally increases in temperature, the portion of the substrate 203a, which corresponds in position to the thermal fuse 206, becomes nonuniform in thermal stress. In other words, this embodiment also can provide the same effects as the first embodiment.
Next, another (fifth) embodiment of the present invention is described.
In the case of the fixing device C in this embodiment, the thermoswitch spacer 210 was placed between the thermoswitch 209 which is similar to the one in the fourth embodiment, and the substrate 203a. Otherwise, the fixing device C in this embodiment is the same in structure as the one in the first embodiment.
Referring to
It is desired that a resinous substance, the melting point of which is such that it melts only as the heater 203 abnormally increases in temperature because the power supply circuit PS is out of control, is used as the material for the thermoswitch spacer 210. That is, it is desired that a resinous substance which is thermally meltable only as the heater 203 abnormally increases in temperature because the power supply circuit PS is out of control, is used as the material for the thermoswitch spacer 210. With a resinous substance which is lower in melting point than the heater holder 204 being used as the material for the thermoswitch spacer 210, as the heater holder 204 melts, the thermoswitch 209 comes into contact with the heat conduction layer 207 on the substrate 203a. Consequently, the thermoswitch 209 functions. Here, the thermoswitch spacer 210 is less in thermal conductivity than the substrate 203a.
The operating temperature of the thermoswitch 209 is no higher than roughly 250° C. Thus, in a case where the fixation temperature needs to be higher than the operating temperature of the thermoswitch 209, the heat sensing portion 209c of the thermoswitch 209 is not to be in contact with the back surface of the substrate 203a. This is why the fixing device C in this embodiment is structured so that the thermoswitch spacer 210 made of the resinous substance, which can thermally melted as described above, is placed between the thermoswitch 209 and heat conduction layer 207.
In the case of the fixing device C in this embodiment, when the heater 203 is normal in operation, a preset amount of gap remains between the heat sensing portion 209b of the thermoswitch 209 and the back surface of the substrate 203a. However, as the power supply circuit PS goes out of control, the thermoswitch spacer 210 melts, and therefore, the heat sensing portion 209b of the thermoswitch 209 comes into contact with the heat conduction layer 207 on the back surface of the substrate 203a. Thus, the heater 203 can be used at a temperature level which is higher than the operating temperature of the thermoswitch 209, and yet, can be prevented from operating as the peripheral surface PS goes out of control. Further, the heat conduction layer 207 is present on the substrate 203a. Therefore, the fixing device C in this embodiment is as small as the fixing device C in the first embodiment, in the amount of thermal stress to which the portion of the substrate 203a, which corresponds in position to the thermoswitch 209, is subjected as the thermoswitch 209 comes into contact with the substrate 203a. In other words, this embodiment is just as effective as the first embodiment to prevent the substrate 203a from cracking.
When the fixing device C in this embodiment was subjected to the same runaway test as the one to which the fixing device C in the first embodiment was subjected, the length of time it took for the thermoswitch 209 to react was 5.6 seconds, whereas the length of time it took for the heater 203 (substrate 203a) to crack was 11.0 seconds. Thus, it is evident that this embodiment provide a satisfactory amount of margin in time between the point in time at which the thermoswitch 209 reacts and the point in time at which the heater 203 (substrate 203a) cracks.
Next, another (sixth) embodiment of the present invention is described.
In the case of the fixing device C in this embodiment, a single heat conduction layer 207 was placed on the back surface of the substrate 203a, and the thermal fuse 206 and thermistor 205 were placed in contact with the heat conduction layer 207. Otherwise, the fixing device C in this embodiment is the same in structure as the one in the first embodiment. Thus, the thermistor 205 detects the temperature of the heater 203 through the heat conduction layer 207. Referring to
The thermal fuse 206 was attached to the substrate 203a, with the above described thermally conductive grease placed between the metallic shell 206a of the thermal fuse 206 and the heat conduction layer 207. The thermistor 205 is attached to the substrate 203a so that its electrical insulation 205d (
The fixing device C in this embodiment was subjected to the same runaway test as the one to which the fixing device C in this embodiment was subjected. The length of time it took for the thermal fuse 206 to open was 6.3 seconds, which is the same as the fixing device C in the first embodiment, whereas the length of time it took for the heater 203 (substrate 203a) to crack was 13.0 seconds. It seems reasonable to think that this is the proof that the cracking which occurred to the portion of the substrate 203a, which corresponds in position to the thermistor 205, when the fixing device C in the first embodiment was subjected to the runaway test, was prevented. That is, this embodiment made it possible to provide a fixing device with an even greater margin in time between the point in time at which the thermal fuse 206 reacts and the point in time at which the heater 203 (substrate 203a) cracks.
The elements other than the thermal fuse 206 and thermistor 205, which are to be placed on the back surface of the substrate 203a, may be placed on the heat conduction layer 207. In the case where the other elements are placed on the back surface of the substrate 203a, the portions of the back surface of the substrate 203a, which correspond in position to the thermal fuse 206, thermistor 206, and the other elements, are rendered uniform in temperature.
As described above, in the case of the fixing device C in this embodiment, the metallic shell 206a of the thermal fuse 206, and the insulator 205d of the thermistor 205, are placed in contact with the heat conduction layer 207, which is placed on the back surface of the substrate 203a and is greater in thermal conductivity than the substrate 203a. Thus, the heat conduction layer 207 can minimize in severity the phenomenon that as the heater 203 abnormally increases in temperature, not only the portion of the substrate 203a, which corresponds in position to the thermal fuse 206, but also, the portion of the substrate 203a, which corresponds in position to the thermistor 205, become nonuniform in thermal stress. In other words, this embodiment also can provide effects similar to the effects which the first embodiment does.
Next, another (seventh) embodiment of the present invention is described.
In the case of the fixing device C in this embodiment, the aluminum plates 208a and 208b as the first and second thermally conductive layers, respectively, are provided on the back surface of the substrate 203a. The thermal fuse 206 was placed in contact with the aluminum plate 208a, and the thermistor 205 was placed in contact with the aluminum plate 208b. Otherwise, the fixing device C in this embodiment was the same in structure as the one in the first embodiment.
That is, in this embodiment, the thermal fuse 206, which is in connection to the primary circuit of the power supply circuit PS, was placed on the aluminum plate 208a, whereas the thermistor 205 which is in connection to the secondary circuit of the power supply circuit PS, was placed on the aluminum plate 208b, being thereby separated from each other in terms of electrical connection. In other words, the fixing device C was structured so that there was no electrical conduction between the aluminum plates 208a and 208b. Thus, even if the heater 203 cracks, the primary current does not flow into the secondary circuit.
The substances which are satisfactory as the material for a thermally conductive member are overwhelmingly such substances as metal, graphite, and the like, which are also electrically conductive. In a case where a component (thermally conductive member) made of such a substance as the abovementioned ones is placed on the back surface of the substrate 203a, and the thermal fuse 206 and thermistor 205 are placed on the thermally conductive member, if the heater 203 (203a) cracks for some reason or the other, it is possible that the primary current from the commercial outlet will directly flow into the secondary circuit. Therefore, it is reasonable to think that if the heater 203 (substrate 203a) cracks, the primary current will flow into the thermistor 205 through the metallic shell 206a of the thermal fuse 206, for example.
Further, once the power supply circuit PS goes out of control due to the malfunctioning of the primary circuit, it is possible that the electrical insulator 205d (
In this embodiment, two aluminum plates 208a and 208b, with which the thermal fuse 206 and thermistor 205 are placed in contact, respectively, are used as the thermally conductive members. Further, the two aluminum plates 208a and 203b are fixed to the back surface of the substrate 203a, with the presence of a preset distance between the two plates 208a and 208b in terms of the lengthwise direction. The preset distance between the two aluminum plates 208a and 208b is 5 mm. This structural arrangement can keep the aluminum plate 208a, with which the metallic shell 206a of the thermal fuse 206 is placed in contact, separated in terms of electrical connection from the aluminum plate 208b, with which the electrical insulator 205d of the thermistor 205 is placed in contact.
The fixing device C in this embodiment was subjected to a runaway test similar to the one to which the fixing device C in the first embodiment was subjected. The length of time it took for the thermal fuse 206 to open was 6.3 seconds, which was the same as the length of time it took for the thermal fuse 206 in the first embodiment to open, whereas the length of time it took for the heater 203 (substrate 203a) to crack was 13.5 seconds. It is evident from these results that this embodiment can keep the primary and secondary circuits of the power supply circuit PS separated from each other, and also, can ensure that the thermal fuse 206 will react before the heater 203 (substrate 203a) cracks as the power supply circuit PS goes out of control.
As described above, in the case of the fixing device C in this embodiment, the two aluminum plates 208a and 208b, which are separated from each other in terms of electrical connection, are placed on the back surface of the substrate 203a of the heater 203. The metallic shell 206a of the thermal fuse 206 is placed in contact with the aluminum plate 208a, and the electrical insulator 205d of the thermistor 205 is placed in contact with the aluminum plate 208b. That is, the presence of the two aluminum plates 208a and 208b, which are separated from each other in terms of electrical connection, can keep the thermal fuse 206 and thermistor 205 separated from each other in terms of electrical connection, and also, minimize in severity the phenomenon that as the heater 203 abnormally increases in temperature, the portion of the substrate 203a, which corresponds in position to the thermal fuse 206, becomes nonuniform in thermal stress. In other words, this embodiment enables the thermal fuse 206 and thermistor 205 to operate without short-circuiting, and also, can provide the effects similar to those which the first embodiment can.
The usage of the fixing device C in this embodiment is not limited to the usage as an apparatus for thermally fixing an unfixed toner image on a sheet of recording medium to the sheet. That is, the fixing device C in this embodiment can be used also as an image heating apparatus (device) for heating a temporarily fixed toner image on a sheet of recording medium, to make the toner image glossy.
Next, another (eighth) embodiment of the present invention is described.
In the case of the fixing device C in this embodiment, the portion b′ of each of the pair of strips 203b of heat generating resistor, which corresponds in position to the area F of the substrate 203a, which is the portion of the substrate 203a, with which the thermal fuse 206 is placed in contact, is made narrower than the rest, and the thermal fuse 206 is attached to the substrate 203a, with the placement of heat conduction layer 207 between itself and substrate 203a, so that it corresponds in position to the narrow portion b′ of the strip 203b of heat generating resistor. Thus, it is possible to prevent the problem that while the heater 203 is started up, the portion of the substrate 203a, which corresponds in position to the thermal fuse 206, is reduced in temperature by the thermal capacity of the thermal fuse 206. This structural arrangement is effective to prevent the problem that as the power supply circuit PS goes out of control, the heater 203 (substrate 203a) cracks.
Referring to
Referring to
The amount of heat which the normal width portion b of the strip 203b of heat generating resistor can generate is different from the amount of heat which the narrow portion b′ of the strip 203b of heat generating resistor can generate. Therefore, as the power supply circuit PS goes out of control, the portions of the substrate 203a, which correspond in position to the borderlines between the normal with portion b of the strips 203b of heat generating resistor, and the narrow portion b′, become greater in thermal stress. Therefore, the heater 203 (substrate 203a) is likely to crack at these borderlines. As a means for dealing with this problem that as the power supply circuit PS goes out of control, the heater 203 (substrate 203a) cracks, it is effective to widen (lengthen) the heat conduction layer 207 so that the heat conduction layer 207 becomes longer than the dimension of the narrow portion b′ of the strip 203b of heat generating resistor in terms of the lengthwise direction, and therefore, can conduct the heat which the narrow portion b′ generates in the lengthwise direction of the substrate 203a through the heat conduction layer 207. In this embodiment, the dimension of the heat conduction layer 207 in terms of the lengthwise direction was 15 mm, which was greater than the dimension of the portion of the substrate 203a, which corresponds in position to the narrow portion b′ of the strip 203b of heat generating resistor.
When the heater 203 of the fixing device C in this embodiment in the image forming apparatus was started up, the portion of the back surface of the substrate 203a, which corresponds in position to the thermal fuse 206, was the same in temperature change as the rest of the back surface of the substrate 203a. Further, even the toner image on the first sheet P of recording medium did not show image defects such as insufficiency in glossiness.
When the fixing device C in this embodiment was subjected to the same runaway test as the one to which the fixing device C in the first embodiment was subjected, the length of time it took for the thermal fuse 206 to open was 5.8 seconds, whereas the length of time it took for the heater 203 (substrate 203a) to crack was 10.0 seconds, which proved that this embodiment provided a sufficient margin in time to prevent the problem that as the power supply circuit PS goes out of control, the heater 203 (substrate 203a) cracks.
During the above-described runaway test, the portions of the surface of the substrate 203a, which are in the recording medium passage and correspond in position to the thermal fuse 206 and strips 203b of heat generating resistor, were measured in temperature by a couple of K thermocouples attached thereto, one for one, as those of the fixing device C in the first embodiment were measured. 10 seconds after the starting of the runaway test, the difference in temperature between the portions of the surfaces of the substrate 203a, which correspond in position to the strips 203c of heat generating resistor and thermal fuse 206, respectively, was 35° C., and the amount of thermal stress was 95.6 MPa/mm2.
Further, in the case of a fixing device made as a comparative fixing device, the back surface of the substrate 203a was not provided with the thermally conductive layer 207 (Ag paste was not coated and fired), and the thermal fuse 206 was attached to the substrate 203a with the placement of thermally conductive grease between the thermal fuse 206 and substrate 203a. This comparative fixing device was subjected to the same runaway test as the one to which the fixing device C in the first embodiment was subjected. The comparative fixing device was the same in structure as the fixing device C in this embodiment. When the comparative fixing device was subjected to the runaway test, it required 6.0 seconds for the thermal fuse 206 to open, whereas the length of time it took for the heater 203 (substrate 203a) to crack was 5.7 seconds. Further, the points of the heater 203 (substrate 203a) at which the heater 203 cracked corresponded in position to the lengthwise ends of the narrow portion b′ of the strip 203b of heat generating resistor.
Further, the difference in temperature between the portions of the surfaces of the substrate 203a, which correspond in position to the strips 203c of heat generating resistor and thermal fuse 206, respectively, was 65° C., and the amount of thermal stress was 177.4 MPa/mm2, 5.5 second after the starting of the runaway test.
Further, in the case of the comparative fixing device, the back surface of the substrate 203a was not provided with the thermally conductive layer 207. Therefore, the end portion 206a1 of the metallic shell 206a of the thermal fuse 206 was in contact with the substrate 203a, and the portions of the substrate 203a, which correspond in position to the borderlines between the normal width portion b and narrow portion b′ of the strip 203b, are subjected to a large amount of thermal stress and also, mechanical stress, which can be thought to be the reason why the heater 203 (substrate 203a) cracked.
As described above, in the case of the fixing device C in this embodiment, the portion b′ of the strip 203b of heat generating resistor, which correspond in position to the area F of the portion F of the substrate 203a, that is, the portion of the substrate 203a, with which the thermal fuse 206 is placed in contact, was narrowed, and the thermal fuse 206 was attached to the substrate 203a, with the placement of the heat conduction layer 207 between the thermal fuse 206 and substrate 203a. The presence of this heat conduction layer 207 can minimize the amount of stress to which the portions of the substrate 203a, which correspond in position to the narrow portion b′ of the strip 203b of heat generating resistor, and the thermal fuse 206, are subjected. Thus, this embodiment also can provide the same effects as those which the first embodiment can provide.
While the invention has been described with reference to the structures disclosed herein, it is not confined to the details set forth, and this application is intended to cover such modifications or changes as may come within the purposes of the improvements or the scope of the claims.
According to the present invention, an image heating apparatus which can prevent its heat generating member from cracking when the heat generating member excessively increases in temperature is provided.
Number | Date | Country | Kind |
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2012-255276 | Nov 2012 | JP | national |
Number | Date | Country | |
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Parent | 14430034 | Mar 2015 | US |
Child | 15787227 | US |