The present invention relates to an image heating apparatus of a belt heating type suitable as an image fixing device (apparatus) to be mounted in an image forming apparatus, such as a copying machine, a facsimile machine, a printer or a multi-function machine of these machines, for forming an image on a recording material by an image forming process such as an electrophotographic process or an electrostatic recording process.
Examples of the image heating apparatus may include a fixing device for fixing or temporarily fixing an unfixed image on the recording material as a fixed image, and a gloss increasing device for increasing gloss of an image by heating the image fixed on the recording material.
In recent years, in the image forming apparatus, from the viewpoint of energy saving, a device (apparatus) having small thermal capacity has been proposed and put into practical use as the fixing device which is the image heating apparatus. As a specific means for decreasing the thermal capacity of the fixing device, an endless belt of a belt heating type (belt fixing type) is used as an image heating member.
In the fixing device of the belt heating type described in Japanese Laid-Open Patent Application (JP-A) Hei 07-6414 and JP-A 2006-293225, a ceramic heater as a heat generating member is disposed in a nip formed between the belt and a pressing member. In the nip, a recording material on which an unfixed toner image is carried is nip-conveyed, and the unfixed toner image is fixed on a surface of the recording material as the fixed image by heat of the heater through the belt. This fixing device includes the heater and the belt which have small thermal capacity, thus having the advantages that a waiting time from power-on of the image forming apparatus until an image formable state of the image forming apparatus is short (quick start property) and that power consumption during stand-by is considerably small (power saving).
With respect to the image forming apparatus (fixing device) of the belt heating type, as a constitution capable of further improving energy efficiency compared with the constitution described above, it would be considered that a heat generating layer for generating heat by energization is provided in the belt and the energy is supplied to the heat generating layer to cause the belt itself to generate heat. That is, in the case where the image is heated in the nip by the heat of the heater through the belt, there is a need to apply a lubricant such as grease onto the heater or form a sliding layer of polyimide or fluorine-containing resin on the heater surface in order to prevent wearing (abrasion) of the inner surface of the belt by friction between the heater and the belt. The lubricant or the sliding layer constitutes thermal resistance between the heater and the belt. This is because when the belt itself is configured to generate heat, the thermal resistance component can be eliminated.
As described in JP-A 2007-272223, in a constitution in which the heat generating layer for generating heat by energization is provided in the belt, there is a need to devise an energization constitution to the heat generating layer. That is, in the case where the image heating member has high rigidity and is a roller member including a core metal which is a rotation shaft to be fixed, a locus of an outer peripheral surface of the image heating member during a rotation operation is stabilized. For that reason, by forming an electrical path through the outer peripheral surface of the core metal, it is possible to easily establish the energization constitution for stably supplying energy (power) from a power source portion to the heat generating member on the roller member side. This is because, however, in the case where the image heating member has low rigidity and is a flexible belt free from the rotation shaft, a behavior during the rotation operation is unstable and therefore it is difficult to employ the constitution for stably supplying the (electric) power from the outer peripheral surface as in the case of the roller member described above. That is, in the constitution in which the power is supplied from the outer peripheral surface of the belt, when an urging force of an energization member against the belt is increased, stable electrical connection between the energization member and the heat generating layer can be established but it is difficult to apply the constitution to the low-rigidity belt since breakage such as buckling is liable to occur. Further, in the case where the energization to the heat generating layer is unstable, reduction in rise time cannot be realized and when the energization becomes unstable during passing of the recording material, the heat generating layer cannot be generate heat corresponding to necessary thermal capacity. For that reason, a so-called cold offset such that the toner image on the recording material cannot be fixed occurs.
A principal object of the present invention is to provide an image heating apparatus, including a belt having a heat generating layer which generates heat, capable of stably supplying power to the heat generating layer.
According to an aspect of the present invention, there is provided an image heating apparatus comprising:
a belt including a heat generating layer for generating heat by energization and including a power receiving portion which has electroconductivity and is electrically connected to the heat generating layer;
a stationary back-up member, provided inside the belt, for sliding on an inner peripheral surface of the belt;
a pressing member for pressing the belt against the back-up member to form a nip in which a recording material is to be nip-conveyed between the belt and itself; and
an electroconductive portion, provided on the back-up member, for supplying electric power to the power receiving portion by being electrically connected to the power receiving portion.
These and other objects, features and advantages of the present invention will become more apparent upon a consideration of the following description of the preferred embodiments of the present invention taken in conjunction with the accompanying drawings.
a) is a schematic view showing a layer structure of a belt,
a) to 5(c) are schematic views each showing an energization constitution with respect to an electroconductive layer.
a) to 6(c) are schematic views each showing an energization constitution with respect to an electroconductive layer in a fixing device in Embodiment 2.
(1) Image Forming Apparatus
A constitution of the image forming apparatus 100 itself will be briefly described. On a basis of a print start signal, an electrophotographic photosensitive drum 1 of each of first to fourth electrophotographic image forming portions Y, M, C and K is rotated in the counterclockwise direction indicated by an arrow at a predetermined speed. An endless belt 7a of an intermediary transfer belt unit 7 is circulated and moved in the clockwise direction indicated by an arrow at a speed corresponding to the rotational speed of the drum 1. A laser scanner 3 is also driven. Each of the image forming portions includes a charging roller 2, the laser scanner 3, a developing device 4, a primary transfer roller 5 and a cleaning device 6, which are process means acting on the drum 1. The belt 7a is extended and stretched around three rollers consisting of a driving roller 7b, a secondary transfer opposite roller 7c and a tension roller 7d. The primary transfer roller 5 press-contacts the belt 7a against a lower surface of the drum 1 at each image forming portion. The contact portion between the drum 1 and the belt 7a constitutes a primary transfer portion T1. A secondary transfer roller 8 press-contacts the belt 7a against the secondary transfer opposite roller 7c. The contact portion between the belt 7a and the secondary transfer roller 8 constitutes a secondary transfer portion T2. On the drum 1 at the first image forming portion Y, a toner image of yellow (Y) corresponding to a yellow component of the full-color image is formed and then is primary-transferred onto the belt 7a at the primary-transfer portion T1 of the first image forming portion Y. On the drum 1 at the second image forming portion M, a toner image of magenta (M) corresponding to a magenta component of the full-color image is formed and then is primary-transferred superposedly onto the toner image of Y, which has already been transferred onto the belt 7a, at the primary transfer portion T1 of the second image forming portion M. On the drum 1 at the third image forming portion C, a toner image of cyan (C) corresponding to a cyan component of the full-color image is formed and then is primary-transferred superposedly onto the toner images of Y and M, which have already been transferred onto the belt 7a at the primary-transfer portion T1 of the third image forming portion Y. On the drum 1 at the fourth image forming portion K, a toner image of black (K) corresponding to a black component of the full-color image is formed and then is primary-transferred superposedly onto the toner images of Y, M and C, which have already been transferred onto the belt 7a, at the primary transfer portion T1 of the fourth image forming portion K. Thus, unfixed toner images of Y, M, C and K for the four-color based full-color image are synthetically formed on the moving belt 7a. These unfixed toner images are conveyed to reach the secondary transfer portion T2 by further movement of the belt 7a.
On the other hand, sheets of the recording material P stacked and accommodated in a sheet feeding cassette 10 are fed one by one with predetermined control timing, and the fed recording material P is conveyed to a registration roller pair 11. The recording material P is then conveyed to the secondary transfer portion T2 with predetermined control timing by the registration roller pair 11. In a process in which the recording material P is nip-conveyed at the secondary transfer portion T2, the superposed four color toner images are collectively secondary-transferred from the belt 7a onto the surface of the recording material P. The recording material P coming out of the secondary transfer portion T2 is separated from the belt 7a and is successively passed through a first fixing device 9(a) and a second fixing device 9(2), so that the toner images are fixed on the recording material P. The fixing of the toner images on the recording material P is performed by applying heat and pressure to the recording material P. The recording material P which has been subjected to the fixing is discharged on a sheet discharging tray 12 as a color-image formed product. Secondary transfer residual toner remaining on the surface of the belt 7a after the secondary transfer of the toner images onto the recording material P is removed by a belt cleaning device 13.
(2) Fixing Device
The fixing device 9 includes a belt assembly 20 as a heating member (fixing member) and a pressing roller 30 as a (rotatable) pressing member. The belt assembly 20 and the pressing roller 30 are vertically arranged in substantially parallel to each other between left and right side plates 41L and 41R of a fixing device frame 40.
The pressing roller 30 has a multi-layer structure including a core metal 30a of stainless steel, a silicone rubber layer 30b as an elastic layer formed on the core metal 30a in a roller shape coaxially with the core metal 30a, and a tube layer 30c of PFA resin as a parting layer (surface layer) formed on the silicone rubber layer 30b. The pressing roller 30 is rotatably supported between the left and right side plates 41L and 41R through bearing members 42 at left and right end portions of the core metal 30a. At a right-side end portion of the core metal 30a, a drive gear G is fixed. A rotational force is transmitted from a driving source (motor) M to the gear G through a power transmitting mechanism (not shown), so that the pressing roller 30 is rotationally driven in the counterclockwise direction indicated by an arrow in
The belt assembly 20 is prepared by assembling the flexible endless belt 21 as the image heating member, the back-up member 22, the supporting stay (urging stay) 23, left and right flange members 24, a thermistor 25 as a temperature detecting member, and the like.
1) Belt 21
a) is a schematic view showing a layer structure of the belt 21. The belt 21 is a cylindrical belt (endless belt which at least includes the heat generating layer 21b for generating heat by energization and which has flexibility as a whole. The belt 21 in this embodiment basically has a four-layer composite structure consisting of a base layer 21a, the heat generating layer 21b, an elastic layer 21c and a parting layer 21d in the order from its inner peripheral surface side to its outer peripheral surface side. That is, the belt 21 includes the heat generating layer 21b formed on the outer peripheral surface of the cylindrical base layer 21a, the elastic layer 21c formed on the outer peripheral surface of the heat generating layer 21b, and the parting layer 21d formed at an outermost peripheral surface. Incidentally,
The base layer 21a is a flexible member which is insulative and has a cylindrical shape. The base layer 21a can be formed of a heat-resistant material in a thickness of 100 μm or less, preferably 50 μm less and 20 μm or more, in order to decrease thermal capacity to improve a quick start property. For example, as the base layer 21a, it is possible to use a resin belt of, e.g., polyimide, polyimideamide, PEEK, PTFE, PFA, FEP, or the like or to use a metal belt of SUS, nickel, or the like for the purpose of enhancing rigidity of the belt. In this embodiment, a cylindrical polyimide belt of 30 μm in thickness and 25 mm in diameter was used. Incidentally, in the case where an electroconductive material is used for forming the base layer 21a, there is a need to provide an insulating layer of polyimide or the like between the base layer 21a and the heat generating layer 21b.
The heat generating layer 21b generates heat by energization and may preferably be formed of a material prepared by mixing an electroconductive material in a resin material. According to this mixed material, it is possible to easily prepare the heat generating layer 21b capable of having various resistance values only by changing a mixing ratio between the resin material and the electroconductive material. In this embodiment, the heat generating layer 21b is a heat generating resistor prepared by applying polyimide resin containing carbon black as electroconductive particles on the base layer 21a in a uniform thickness of about 10 μm. A total resistance value of the heat generating layer 21b is 10.0Ω. Therefore, electric power (amount of heat generation) consumed during application of a commercial voltage of 100 V from an AC voltage source (power source) is 1000 W.
As the elastic layer 21c in this embodiment, a 300 μm-thick silicone rubber layer having a rubber hardness of 10 degrees (JIS-A hardness) and a thermal conductivity of 1.3 W/m.K was used.
The parting layer 21d is the surface layer of the belt 21 and may preferably be formed of fluorine-containing resin. The parting layer 21d is formed of the fluorine-containing resin having high parting property, so that it is possible to obtain a parting performance between the belt 21 and the toner on the recording material P and to prevent toner offset. In this embodiment, as the parting layer 21d, a 20 μm-thick PFA tube was used. Further, as the parting layer 21d, a PFA coating layer may also be used. Depending on necessary thickness, mechanical strength and electrical strength, the PFA tube and the PFA coating layer can appropriately be selected and used. Further, the parting layer 21d is bonded to the elastic layer 21c with an adhesive of silicone resin.
2) Back-Up Member 22
The back-up member 22 is an elongated member which is inserted into the belt 21 and has a substantially semicircular tub-like shape in cross section and further has rigidity, heat resistance and heat insulating property. On an outer surface of the back-up member 22, the inner peripheral surface of the belt 21 slides. The back-up member 22 may desirably be formed of a material which less conducts the heat to the supporting stay 23 from the viewpoint of energy saving and may be formed of, e.g., heat-resistant glass or heat-resistant resin such as polycarbonate or liquid crystal polymer. Further, as described later, a constitution in which the power is supplied to the heat generating layer 21b of the belt 21 through the electroconductive portion provided on the back-up member 22 is employed in this embodiment and therefore it is essential to use the insulating material as the material for the back-up member 22. In this embodiment, as the material, “SUMIKA SUPER E5204L”, mfd. by Sumitomo Chemical Company was used. The back-up member 22 functions as a rotation guide of the belt 21 which is loosely and externally engaged on the back-up member 22. Further, the back-up member 22 also functions as a means for pressing (urging) the belt 21 toward the pressing roller 30.
3) Supporting Stay 23
The supporting stay 23 is an elongated rigid member which is provided inside the back-up member 22 and has a downward (reversed) U shape in cross section. The supporting stay 23 may desirably be formed of a material which is less bent even when a high pressure is applied thereto. In this embodiment, SUS 304 was used. The supporting stay 23 supports the back-up member 22.
4) Flange Member 24
The left and right flange members 24 are a regulating (preventing) member for preventing lateral movement (deviation) of the belt 21 toward a left end or a right end along a longitudinal direction of the back-up member during the rotation of the belt 21 and for regulating a shape of the belt 21 with respect to a circumferential direction of the belt 21 during the rotation of the belt 21. The left and right flange members 24 are bilaterally symmetrical and are engaged and fitted on left and right outwardly extended arm portions 23a of the supporting stay 23.
5) Thermistor 25
The thermistor 25 is disposed above the supporting stay 23 so as to be elastically contacted to the inner surface of the belt 21 and has the function of detecting a temperature of the inner surface of the belt 21. Specifically, the thermistor 25 is mounted on an end portion of a stainless steel arm 26 fixed and supported on the supporting stay 23 and is placed in a state in which the thermistor is elastically contacted to the inner surface of the belt 21 by externally engaging the belt 21 on the back-up member 22 and the supporting stay 23. Further, the arm 26 is elastically swung, so that the thermistor 25 is kept in the state in which the thermistor 25 is always contacted to the inner surface of the belt 21 even in a state in which motion of the inner surface of the belt 21 becomes unstable.
Then, the belt assembly 20 which is the assembled member of the above-described members 21 to 25 and the like is arranged on the pressing roller 30 in substantially parallel to the pressing roller 30 with a downward back-up member 22 side and is disposed between the left and right side plates 41L and 41R of the device frame 40. The left and right flange members 24 are provided with vertical groove portions 24c (
Then, the rotational force is transmitted from the driving source M to the drive gear G of the pressing roller 30, so that the pressing roller 30 is rotationally driven in the counterclockwise direction at the pressing roller speed as shown in
Further, by the energization constitution described later, the power is supplied to the heat generating layer 21b of the rotating belt 21. The belt 21 is head by the heat generation of the heat generating layer 21b to increase in temperature, and the temperature of the belt 21 is detected by the thermistor 25. The thermistor 25 is connected to the control circuit portion 200 as a control means through an A/D converter 201 (
In a state in which the belt 21 is increased in temperature up to a preset temperature and temperature-controlled at the temperature by rotating the belt 21 by the rotation of the pressing roller 30 and then by supplying the power to the heat generating layer 21b, the recording material P carrying thereon the unfixed toner images t is introduced along a guide 27 into the nip N. In the nip N, the toner image carrying surface of the recording material P intimately contacts the outer surface of the belt 21, so that the recording material P moves together with the belt 21. In a nip-conveying process of the recording material P in the nip N, the heat generated by the heat generating layer 21b is applied to the recording material P, so that the unfixed toner images (images) t are melted and fixed on the recording material P. The recording material P having passed through the nip N is separated by curvature and then is discharged by fixing discharge rollers 28.
In this embodiment, the recording material P is passed through the nip N on a recording material width center line basis, i.e., by a so-called center line-based conveyance. In
(3) Energization Constitution
The energization constitution with respect to the heat generating layer 21b of the belt 21 will be described.
On the other hand, the back-up member 22 includes the outwardly extended arm portions 22a which are provided by extending the lower surface portions thereof, constituting the nip N, leftward and rightward. Further, as shown in
Thus, the back-up member 22 includes the first electroconductive portion 76 and the second electroconductive portion 77 in the area in which the back-up member 22 urges the belt 21 and in the area in which these portions 76 and 77 oppose the power supplying portion 71 and the power receiving portion 72 of the belt 21, respectively, with respect to the longitudinal direction. Further, the first electroconductive portion 76 and the second electroconductive portion 77 are extended outside the belt ends at their outside end portions and contact the power supplying members 81a and 82a, respectively, to be electrically connected to the power source portion 202 in areas outside the belt 21.
That is, at the inner surface of the belt 21, the power supplying portion 71 and the power receiving portion 72 are provided. Further, the back-up member 22 is provided with the first electroconductive portion 76 and the second electroconductive portion 77 which contact the power supplying portion 71 and the power receiving portion 72, respectively. Further, in the nip N, the power supplying portion 71 and the first electroconductive portion 76 contact each other and the power receiving portion 72 and the second electroconductive portion 77 contact each other, and the first and second electroconductive portions 76 and 77 are electrically connected to the power source portion 202. Therefore, an energization path for the heat generating layer 21b is constituted by the power source portion 202, a lead 81b, the power supplying member 81, the first electroconductive portion 76, the power supplying portion 71, the conductive path 75, the heat generating layer 21b, the conductive path 75, the power receiving portion 72, the second electroconductive portion 77, the power supplying member 82, a lead 82b, and the power source portion 202. The power source portion 202 is controlled by the control circuit portion 200. By turning on the power source portion 202, the power is supplied to the heat generating layer 21b through the energization path described above, so that the belt 21 is heated to be increased in temperature by the heat generation of the heat generating layer 21b. The temperature of the belt 21 is detected by the thermistor 25, and detection temperature information of the thermistor 25 is inputted into the contact circuit portion 200 through the A/D converter 201. The control circuit portion 200 samples, as described above, the output from the thermistor 25 at the pressing roller interval and reflects the resultant temperature information in the control of the energization to the heat generating layer 21b.
Also during the rotation of the belt 21, the back-up member 22 is in a rest state, so that the electrical connection between the power supplying member 81 and the first electroconductive portion 76 and between the power supplying member 82 and the second electroconductive portion 77 is satisfactorily maintained. Further, the back-up member 22 presses and urges the belt 21 including the power supplying portion 71 and the power receiving portion 72, so that the electrical connection between the first electroconductive portion 76 and the power supplying portion 71 and between the second electroconductive portion 77 and the power receiving portion 72 is also satisfactorily maintained. By the constitution in this embodiment, the electrical connection between the power source portion 202 and the heat generating layer 21b can be stably maintained also during the drive of the fixing device 9.
That is, a locus of the belt 21 during the rotational drive is stable in the nip N in which the belt 21 is press-contacted to the pressing roller 30. For that reason, the power can be stably supplied to the heat generating layer 21b by electrically connecting the power supplying portion 71 and the power receiving portion 72 of the belt 21 to the power source portion 202 in the nip N. The power supplying portion 71 and the power receiving portion 72 of the belt 21 are electrically connected to the power source portion 202 through the first electroconductive portion 76 and the second electroconductive portion 77, respectively, provided on the back-up member 22 which presses and urges the belt 21 toward the pressing roller 30. As a result, stable power supply from the power source portion 202 to the heat generating layer 21b can be realized. Through the conductive paths 75, the power supplying portion 71 and the power receiving portion 72 which are provided as an innermost layer of the belt 21 and contact the first electroconductive portion 76 and the second electroconductive portion 77, respectively, are electrically connected to the heat generating layer 21b provided on the outer peripheral surface of the base layer 21a of the belt 21. As a result, from the power source portion 202 to the heat generating layer 21b, the power can be supplied stably.
Further, in the fixing device 9 in this embodiment, with respect to the direction perpendicular to the recording material conveyance direction a in the nip N, the maximum sheet passing width WPmax of the recording material P is within (inside) a heat generation area width W21b of the heat generating layer 21b. The recording material P passes through the nip N with in the heat generation area width W21b of the heat generating layer 21b, so that a whole area of the recording material P can be heated. Further, the heat generation area width W21b of the heat generating layer 21b is 307 mm and the maximum sheet passing width WPmax of the recording material P is 297 mm, so that the heat generating layer 21b is longer than the recording material P by 5 mm on each of the left and right sides thereof. With respect to the temperature of the belt, a change (variation) in temperature occurs in the neighborhood of the end portions of the heat generating layer 21b due to the thermal transmission toward the end portions and therefore there is a need to make the heat generation area width W21b of the heat generating layer 21b larger than the maximum sheet passing width WPmax of the recording material P. Further, in the case where the heat generation area width W21b is excessively larger than the maximum sheet passing width WPmax, excessive temperature rise occurs in an area in which the recording material P does not pass, to that the belt 21 can be broken. In this embodiment, the heat generation area width W21b is made larger than the maximum sheet passing width WPmax by 5 mm on each of the left and right end portion sides, so that prevention of the change in temperature and prevention of the excessive temperature rise at recording material end positions are compatibly realized. Incidentally, each of
As described above, according to this embodiment, in the fixing device 9 using the belt 21 including the heat generating layer 21b for generating heat by energization, it is possible to realize stable electric power supply to the heat generating layer 21b.
a), 6(b) and 6(c) are schematic views for illustrating a constitution in this embodiment. In this embodiment, the belt 21 has a four-layer composite structure consisting of the heat generating layer 21b, the base layer 21a, the elastic layer 21c and the parting layer 21d in the order from its inner peripheral surface side to its outer peripheral surface side. That is, the belt 21 includes the heat generating layer 21b formed on the inner peripheral surface of the cylindrical base layer 21a, the elastic layer 21c formed on the outer peripheral surface of the base layer 21a, and the parting layer 21d formed at an outermost peripheral surface.
On the left and right sides of the belt 21, the power supplying portion 71 and the power receiving portion 72 which have electroconductivity and a ring-like shape with respect to the circumferential direction are formed, respectively, on the inner surface of the base layer 21a of the belt 21. Further, the power supplying portion 71 and the power receiving portion 72 are electrically connected to the left and right ends of the heat generating layer 21b, respectively, through the conductive paths 75. That is, the conductive paths 75 for electrically connecting the power supplying portion 71 and the power receiving portion 72 to the heat generating layer 21b are formed at the innermost surface of the belt 21. The conductive paths 75 may only be required to be electrically connecting the power supplying portion 71 and the power receiving portion 72 to the heat generating layer 21b and thus may be free from a ring-like electroconductive pattern. Other constitutions are similar to those in Embodiment 1, and therefore in this embodiment, constituent members or portions common to Embodiment 1 are represented by the same reference numerals or symbols and will be omitted from redundant description.
Also in this embodiment, the back-up member 22 includes, as shown in
That is, an energization path for the heat generating layer 21b is constituted by the power source portion 202, a lead 81b, the power supplying member 81, the first electroconductive portion 76, the power supplying portion 71, the conductive path 75, the heat generating layer 21b, the conductive path 75, the power receiving portion 72, the second electroconductive portion 77, the power supplying member 82, a lead 82b, and the power source portion 202.
Also during the rotation of the belt 21, the back-up member 22 is in a rest state, so that the electrical connection between the power supplying member 81 and the first electroconductive portion 76 and between the power supplying member 82 and the second electroconductive portion 77 is satisfactorily maintained. Further, the back-up member 22 presses and urges the belt 21 including the power supplying portion 71 and the power receiving portion 72, so that the electrical connection between the first electroconductive portion 76 and the power supplying portion 71 and between the second electroconductive portion 77 and the power receiving portion 72 is also satisfactorily maintained. That is, by the constitution in this embodiment, the electrical connection between the power source portion 202 and the heat generating layer 21b can be stably maintained also during the drive of the fixing device 9.
That is, a locus of the belt 21 during the rotational drive is stable in the nip N in which the belt 21 is press-contacted to the pressing roller 30. For that reason, the power can be stably supplied to the heat generating layer 21b by electrically connecting the power supplying portion 71 and the power receiving portion 72 of the belt 21 to the power source portion 202 in the nip N. The power supplying portion 71 and the power receiving portion 72 of the belt 21 are electrically connected to the power source portion 202 through the first electroconductive portion 76 and the second electroconductive portion 77, respectively, provided on the back-up member 22 which presses and urges the belt 21 toward the pressing roller 30. As a result, stable power supply from the power source portion 202 to the heat generating layer 21b can be realized. Through the conductive paths 75, the power supplying portion 71 and the power receiving portion 72 which are provided as an innermost layer of the belt 21 and contact the first electroconductive portion 76 and the second electroconductive portion 77, respectively, are electrically connected to the heat generating layer 21b provided on the innermost peripheral surface of the belt 21. As a result, from the power source portion 202 to the heat generating layer 21b, the power can be supplied stably.
Further, also in the fixing device 9 in this embodiment, with respect to the direction perpendicular to the recording material conveyance direction a in the nip N, the maximum sheet passing width WPmax of the recording material P is within (inside) a heat generation area width W21b of the heat generating layer 21b. Further, the heat generation area width W21b of the heat generating layer 21b is 307 mm and the maximum sheet passing width WPmax of the recording material P is 297 mm, so that the heat generating layer 21b is longer than the recording material P by 5 mm on each of the left and right sides thereof. As a result, similarly as in the case of the fixing device 9 in Embodiment 1, prevention of the change in temperature and prevention of the excessive temperature rise at recording material end positions are compatibly realized.
In the fixing device 9 in this embodiment, the belt 21 at least includes the heat generating layer 21b for generating heat by energization and includes the power supplying portion 71 and the power receiving portion 72 which are provided at the outermost surface of the belt 21 and are electrically connected to the heat generating layer 21b to possess the electroconductive property. Further, the pressing roller 30 includes the first electroconductive portion 76 and the second electroconductive portion 76 at portions corresponding to the power supplying portion 71 and the power receiving portion 72 of the belt 21, respectively. Further, the first electroconductive portion 76 and the second electroconductive portion 77 are electrically connected to the power source portion 202 for supplying the power to the heat generating layer 21b.
More specifically, the belt 21 in this embodiment basically has, similarly as in the case of the belt 21 in Embodiment 1, the four-layer composite structure consisting of the base layer 21a, the heat generating layer 21b, the elastic layer 21c and the parting layer 21d in the order from its inner peripheral surface side to its outer peripheral surface side. That is, the belt 21 includes the heat generating layer 21b formed on the outer peripheral surface of the cylindrical base layer 21a, the elastic layer 21c formed on the outer peripheral surface of the heat generating layer 21b, and the parting layer 21d formed at the outermost peripheral surface.
On the left and right sides of the outer surface of the belt 21, the power supplying portion 71 and the power receiving portion 72 which have electroconductivity and a ring-like shape with respect to the circumferential direction are formed, respectively. Further, the power supplying portion 71 and the power receiving portion 72 are electrically connected to the left and right ends of the heat generating layer 21b, respectively, through the conductive paths 75. That is, the conductive paths 75 for electrically connecting the power supplying portion 71 and the power receiving portion 72 to the heat generating layer 21b are formed via the end portions of the belt 21. The conductive paths 75 may only be required to be electrically connecting the power supplying portion 71 and the power receiving portion 72 to the heat generating layer 21b and thus may be free from a ring-like electroconductive pattern.
The pressing roller 30 is provided with the first electroconductive portion 76 on the left electroconductive portion side and the second electroconductive portion 77 on the right end portion side in a ring-like shape with respect to the circumferential direction at the outer surface thereof. The first electroconductive portion 76 and the second electroconductive portion 77 are provided in areas in which the portions 76 and 77 oppose the power supplying portion 71 and the power receiving portion 72, respectively, provided on the belt 21. The first electroconductive portion 76 is formed by being extended to cover the left-side end surface the pressing roller 30 and the left-side end portion of the core metal 30a. The second electroconductive portion 77 is formed by being extended to cover the right-side end surface of the pressing roller 30 and the right-side end portion of the pressing roller 30. That is, the first and second electroconductive portions 76 and 77 are formed so as to cover from the area in which the portions 76 and 77 oppose the power supplying portion 71 and the power receiving portion 72 of the belt 21 to the exposed portions of the core metal 30a of the pressing roller 30. In this case, the pressing roller 30 includes the core metal 30a of stainless steel which is the electroconductive material and therefore an insulating layer 90 is formed between the core metal 30a and the first electroconductive portion 76 and between the core metal 30a and the second electroconductive portion 77 to prevent electrical short therebetween. In the neighborhood of the center of the shaft of the core metal 30a at left and right end surfaces, the power supplying members 81 and 82 are elastically contacted to the first and second electroconductive portions 76 and 77, respectively. The power supplying members 81 and 82 are a leaf spring-like member of stainless steel. That is, an energization path for the heat generating layer 21b is constituted by the power source portion 202, a lead 81b, the power supplying member 81, the first electroconductive portion 76, the power supplying portion 71, the conductive path 75, the heat generating layer 21b, the conductive path 75, the power receiving portion 72, the second electroconductive portion 77, the power supplying member 82, a lead 82b, and the power source portion 202.
As described above, in this embodiment, the core metal 30a of the pressing roller 30 is formed of the electroconductive material and the exposed shaft portion of the core metal 30a is coated with the insulating material 90 and is further coated with the electroconductive material which is electrically connected to the first and second electroconductive portions 76 and 77. Further, the electrical connection between the first electroconductive portion 76 and the power source portion 202 and between the second electroconductive portion 77 and the power source portion 202 is performed at the center of the shaft of the pressing roller 30. In the case where the core metal 30a of the pressing roller 30 is formed of the insulating material, the exposed shaft portion is coated with the electroconductive material which is electrically connected to the first and second electroconductive portions 76 and 77. Further, with respect to the direction perpendicular to the recording material conveyance direction a in the nip N, the power supplying portion 71 and the power receiving portion 72 are located outside the maximum sheet passing width WPmax of the recording material P. A difference in length at a boundary between the power source (belt surface layer) 21d and the power supplying portion 71 of the belt 21 and at a boundary between the parting layer 21d and the power receiving portion 72 of the belt 21 may desirable be 100 μm or less. Further, a difference in height at a boundary between the parting layer (rotatable pressing member surface layer) 30c and the first electroconductive portion 76 of the pressing roller 30 and at a boundary between the parting layer 30c and the second electroconductive portion 77 of the pressing roller 30 may desirably be 100 μm or less.
In the fixing device 9 in this embodiment, during the rotation of the pressing roller 30, there is almost no influence of a difference in peripheral speed, so that the electrical connection between the power supplying member 81 and the first electroconductive portion 76 and between the power supplying member 82 and the second electroconductive portion 77 is satisfactorily maintained. Further, the back-up member 22 presses and urges the belt 21 including the power supplying portion 71 and the power receiving portion 72 and there is almost no influence of the difference in peripheral speed, so that the electrical connection between the first electroconductive portion 76 and the power supplying portion 71 and between the second electroconductive portion 77 and the power receiving portion 72 is also satisfactorily maintained. That is, by the constitution in this embodiment, the electrical connection between the power source portion 202 and the heat generating layer 21b can be stably maintained also during the drive of the fixing device 9.
Further, also in the fixing device 9 in this embodiment, with respect to the direction perpendicular to the recording material conveyance direction a in the nip N, the maximum sheet passing width WPmax of the recording material P is within (inside) a heat generation area width W21b of the heat generating layer 21b. Further, the heat generation area width W21b of the heat generating layer 21b is 307 mm and the maximum sheet passing width WPmax of the recording material P is 297 mm, so that the heat generating layer 21b is longer than the recording material P by 5 mm on each of the left and right sides thereof. As a result, similarly as in the case of the fixing devices 9 in Embodiments 1 and 2, prevention of the change in temperature and prevention of the excessive temperature rise at recording material end positions are compatibly realized.
As described above, according to this embodiment, in the fixing device using the belt 21 including the heat generating layer 21b for generating heat by energization, stable electric power supply to the heat generating layer 21b can be realized.
Here, the fixing device constitutions in Embodiments 1 to 3 described above do not limit the scope of the present invention and thus the constituent elements and materials of the image forming apparatus and the fixing device, particularly the belt 21 can be variously modified.
As described hereinabove, according to the present invention, with respect to the image heating apparatus using the belt including the heat generating layer for generating heat by energization, it is possible to realize stable electric power supply to the heat generating layer.
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 purpose of the improvements or the scope of the following claims.
This application claims priority from Japanese Patent Application No. 274338/2009 filed Dec. 2, 2009, which is hereby incorporated by reference.
Number | Date | Country | Kind |
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2009-274338 | Dec 2009 | JP | national |
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