This application is based on and claims priority under 35 USC 119 from Japanese Patent Application No. 2013-252315 filed Dec. 5, 2013.
The present invention relates to a heating device, a fixing device, and an image forming apparatus.
According to an aspect of the invention, there is provided a heating device that heats a belt which transports a medium on which a non-fixed image to be fixed onto the medium through heating is formed, the heating device including:
a heating element;
a first insulating layer and a second insulating layer that are arranged to nip the heating element;
a first supporting layer that comes into contact with the first insulating layer and a second supporting layer that comes into contact with the second insulating layer, both of which are arranged to nip the first insulating layer, the heating element, and the second insulating layer; and
a connection member that connects the first supporting layer and the second supporting layer in a normal direction of the first supporting layer and the second supporting layer.
Exemplary embodiments of the present invention will be described in detail based on the following figures, wherein:
Developing units 13Y, 13M, 13C, and 13K form toner images on a sheet P. The signs of Y, M, C, and K mean that these are configured to correspond respectively to yellow, magenta, cyan, and black toner. The developing units 13Y, 13M, 13C, and 13K have no large difference in configuration from one another, except that the toner which are used are different. Hereinafter, the developing units 13Y, 13M, 13C, and 13K are referred to as “developing units 13”, with the alphabets showing the colors of the toner at the ends of the respective signs omitted, when the developing units 13Y, 13M, 13C, and 13K do not have to be distinguished from one another.
Each of the developing units 13 has a photoconductor drum 31, a charging unit 32, an exposure device 33, a developing unit 34, a primary image transfer roller 35, and a drum cleaner 36. The photoconductor drum 31 is an image holding member that has a charge generation layer and a charge transporting layer, and is rotated in an arrow D13 direction in the drawing by a driving unit (not illustrated). The charging unit 32 charges an outer surface of the photoconductor drum 31. The exposure device 33 has a laser light-emitting source (not illustrated), a polygon mirror (not illustrated), and the like, and irradiates the photoconductor drum 31 that is charged by the charging unit 32 with laser light corresponding to the image data under the control by the control unit 11. In this manner, a latent image is held in each of the photoconductor drums 31. The above-described image data may be acquired by the control unit 11 from an external device via a communication unit (not illustrated). Examples of the external device include a reader that reads an original image, and a storage device that stores data showing an image.
The developing unit 34 accommodates toner of any of the Y, M, C, and K colors and a two-component developer containing a magnetic carrier such as ferrite powder. When a tip of a magnetic brush that is formed in the developing unit 34 comes into contact with the outer surface of the photoconductor drum 31, the toner adheres to a part of the outer surface of the photoconductor drum 31 that is exposed by the exposure device 33, that is, a streak portion of an electrostatic latent image and the image is formed (developed) in the photoconductor drum 31.
An intermediate image transfer belt 41 of a transfer portion 14 generates a predetermined potential difference at a position facing the photoconductor drum 31, and the primary image transfer roller 35 transfers the image to the intermediate image transfer belt 41 by using the potential difference. The drum cleaner 36 removes the non-transferred toner that remains on the outer surface of the photoconductor drum 31 after the image transfer, and removes electricity of the outer surface of the photoconductor drum 31. In other words, the drum cleaner 36 removes unnecessary toner and a charge from the photoconductor drum 31 in preparation for subsequent image formation.
The transfer portion 14 has the intermediate image transfer belt 41, a secondary image transfer roller 42, a belt transport roller 43, and a backup roller 44. The transfer portion 14 is a transfer portion that transfers the image, which is formed by the developing units 13, onto the sheet P, the type of which is determined according to the user operation. The intermediate image transfer belt 41 is an endless belt member, and the belt transport roller 43 and the backup roller 44 stretches the intermediate image transfer belt 41. At least one of the belt transport roller 43 and the backup roller 44 is provided with a driving unit (not illustrated) that moves the intermediate image transfer belt 41 in an arrow D14 direction in the drawing. The belt transport roller 43 or the backup roller 44 that is not provided with the driving unit is driven to rotate with following the movement of the intermediate image transfer belt 41. As the intermediate image transfer belt 41 is moved in the arrow D14 direction in the drawing and is rotated, the image on the intermediate image transfer belt 41 is moved to an area nipped by the secondary image transfer roller 42 and the backup roller 44.
The secondary image transfer roller 42 transfers the image on the intermediate image transfer belt 41 onto the sheet P, which is transported from a transport unit 16, by using the potential difference between the secondary image transfer roller 42 and the intermediate image transfer belt 41. A belt cleaner 49 removes the non-transferred toner that remains on an outer surface of the intermediate image transfer belt 41. Then, the transfer portion 14 or the transport unit 16 transports the sheet P, where the image is transferred, to a fixing unit 15. The developing unit 13 and the transfer portion 14 are examples of image forming unit that form the image on a medium of the exemplary embodiment of the invention.
The transport unit 16 (example of a transport unit) has containers and transport rollers. The sheet P as an example of the medium, which is cut to a predetermined size and has the non-fixed image, which is fixed onto the medium through heating, formed thereon, is accommodated in the container. As for the size of the sheet P, at least two different sizes are determined in a direction vertical to a transport direction, that is, a width direction. Herein, two types of the sheets P are used, one being a maximum width sheet P1 and the other being a small width sheet P2 that is narrower in width than the maximum width sheet P1. The maximum width sheet P1 refers to the sheet having the largest size in the width direction among the sheets P handled by the image forming apparatus 1. The two types of the sheets P are distinguished by the control unit 11 according to the containers in which the sheets P are accommodated. The sheets P that are accommodated in the respective containers are taken out, sheet by sheet, by the instruction from the control unit 11 and the transport rollers, and are transported to the transfer portion 14 through a sheet transport path. The medium is not limited to the sheet. For example, the medium may be a resinous sheet. In short, the medium may be any medium insofar as the image may be formed on an outer surface of the medium.
The fixing unit 15 (example of a fixing device) fixes the image, which is transferred to the sheet P, through heating.
The fixing unit 15 has a fixing belt 51, a pressurizing roller 52, a pressing pad 56, a holder 57, and a heating unit 58. As illustrated in
The pressing pad 56, the holder 57, and the heating unit 58 are arranged on an inner circumferential side of the fixing belt 51. The holder 57 is a rod-shaped member that extends in the X-axis direction, and both end portions (not illustrated) of the holder 57 are fixed to a housing of the image forming apparatus 1. The holder 57 is formed by using a heat-resistant resin such as glass-filled PPS (polyphenylene sulfide) and a non-magnetic metal such as gold (Au), silver (Ag), aluminum (Al), and copper (Cu). The holder 57 supports the pressing pad 56 to press the pressing pad 56 in an arrow D56 direction (−Y direction) illustrated in
The pressing pad 56 is formed of a heat-resistant resin such as liquid crystal polymer (LCP), and is supported by the holder 57 at a position facing the pressurizing roller 52. The pressing pad 56 is arranged in a state where the pressing pad 56 is pressed from the pressurizing roller 52 via the fixing belt 51, and presses the fixing belt 51 from inside toward the direction (−Y direction) of the pressurizing roller 52. In this manner, a nip area R1 is formed between the fixing belt 51 and the pressurizing roller 52. The sheet P is transported to pass through the nip area R1. In the nip area R1, the pressing pad 56 is deformed to be recessed toward the axis O1 due to the pressing by the pressurizing roller 52, and the fixing belt 51 has a shape that follows the deformed shape of the pressing pad 56. The pressing pad 56 may be formed of an elastomer such as silicone rubber and fluorine rubber.
The heating unit 58 is a member that heats the fixing belt 51. The heating unit 58 is an example of a heating device according to the exemplary embodiment of the invention. The heating unit 58 is provided with a metal layer 581 (example of a first supporting layer), an insulating layer 582, a metal layer 583, an insulating layer 584, and a metal layer 585 (example of a second supporting layer) that are stacked in this order from an inner circumferential surface side of the fixing belt 51 toward the axis O1. The heating unit 58 has a shape in which a rectangular planar member, where the metal layer 581, the insulating layer 582, the metal layer 583, the insulating layer 584, and the metal layer 585 are laminated, is curved in an arc shape about the axis O1. The heating unit 58 has a plane size of, for example, approximately 100 mm×400 mm in a non-curved state. The heating unit 58 may be formed by being curved after the metal layer 581, the insulating layer 582, the metal layer 583, the insulating layer 584, and the metal layer 585 that have planar shapes are laminated, or may be formed by laminating the metal layer 581, the insulating layer 582, the metal layer 583, the insulating layer 584, and the metal layer 585 that have curved shapes.
In this exemplary embodiment, the metal layer 581 is a stainless steel layer with a thickness of 10 μm to 100 μm. The metal layer 581 has functions as a temperature equalizer and a heat-accumulation material. In addition, the metal layer 581 functions to prevent floating and peeling, which are caused by a thermal expansion of the metal layer 583 and the insulating layers 582 and 584, by using rigidity of the metal layer 581. A surface of the metal layer 581 on the side opposite to the insulating layer 582, that is, an outer surface that is an outer side when the heating unit 58 has an arc shape, comes into contact with the fixing belt 51 to support the fixing belt 51. Examples of shapes of the metal layer 581 include a shape in which a part corresponding to a range (for example, 30° to 180°) of a predetermined central angle is cut from an alloy formed into a cylindrical shape with the thickness described above. However, the shape is not particularly limited.
The metal layer 583 is covered by the insulating layer 582 and is positioned inside the metal layer 581. In this exemplary embodiment, the metal layer 583 is disposed over a direction (longitudinal direction of the heating unit 58) that intersects with the arrow D51 direction, which is the direction in which the fixing belt 51 is moved.
As illustrated in
Referring back to
In this exemplary embodiment, the metal layer 585 is a stainless steel layer with a thickness of 10 μm to 100 μm. The metal layer 585 supports the metal layer 583, the insulating layer 582, and the insulating layer 584, and functions to prevent the floating and the peeling, which are caused by the thermal expansion of the metal layer 583 and the insulating layers 582 and 584 by using rigidity of the metal layer 585. Examples of shapes of the metal layer 585 include a shape in which a part corresponding to a range (for example, 30° to 180°) of a predetermined central angle is cut from an alloy formed into a cylindrical shape with the thickness described above. However, the shape is not particularly limited.
In fixing devices of the related art, a heat generating portion has a higher temperature than an insulating layer, particularly at a timing immediately after an initiation of heat generation, when the heat generating portion and the insulating layer has the same thermal expansion coefficient and when the thermal expansion coefficient of the heat generating portion is higher than the thermal expansion coefficient of the insulating layer. Accordingly, the amount of expansion of the heat generating portion is greater than the amount of expansion of the insulating layer, and a gap (floating and peeling) is generated between the heating element and the insulating layer. This becomes more remarkable when an adhesive force between the heating element and the insulating layer is reduced by use over time at an abnormally high temperature. When the gap is generated between the heat generating portion and the insulating layer, the heat that is generated by the heat generating portion may not be moved to a fixing belt and the fixing belt may not be heated to a predetermined temperature. This results in fixing failures in some cases.
Another problem is that the highly heat-resistant insulating layer is subjected to change such as embrittlement and carbonization, due to an abnormally high temperature caused by an individual heating state (so-called boiling state) of the heating element, when a metal plate is laminated on a side where the heating element and the fixing belt are in contact with each other and the gap (floating and peeling) is generated. As a result, an insulating function is reduced and electric currents flowing in the heating element leak to the metal layer to cause a low resistance area to be formed on a circuit. In this case, combined resistance of the heat generating portion is reduced and abnormal heat generation or the like occurs in some cases.
In contrast, in this exemplary embodiment, the metal layer 581 and the metal layer 585 are connected with the adhesive in the normal direction of the surfaces thereof, and thus the insulating layer 582 and the insulating layer 584, which are nipped between the metal layer 581 and the metal layer 585 are pressed from outside with respect to the metal layer 583 arranged therebetween. As a result, the gap formation (occurrence of the floating and the peeling) is suppressed between the metal layer 583 and the insulating layers 582 and 584.
In addition, in this exemplary embodiment, the laminated body of the insulating layer 582, the metal layer 583, and the insulating layer 584 is arranged to be nipped, and the metal layer 581 and the metal layer 585, which are adhered to the laminated body, are deformed to be curved such that the heating unit 58 is formed. A circumferential direction distance of an inner side surface of the heating unit 58 is shorter than a circumferential direction distance of an outer side surface of the heating unit 58, and thus the metal layer 585, in which any of the direction along the surfaces is suppressed by the adhesive 586 during the curving deformation, generates a force toward an outer side of the surface in the normal direction and presses the laminated body of the insulating layer 582, the metal layer 583, and the insulating layer 584 to the metal layer 581. As a result, adhesion between the insulating layer 582 and the metal layer 583 and adhesion between the metal layer 583 and the insulating layer 584 are higher than when the curving deformation is not performed. As such, the gap formation is suppressed.
In addition, in this exemplary embodiment, the thermoplastic adhesive is employed as the adhesive 586. Accordingly, when the metal layer 583 generates heat and reaches a high temperature, liquidity of the adhesive 586 in the vicinity thereof increases. Even when a misalignment is generated between the layers constituting the heating unit 58 due to the difference between the thermal expansion coefficients, the adhesive 586 maintains the adhesion state while allowing the misalignment. Then, when the heat generation of the metal layer 583 is stopped and the temperature is decreased, the adhesive 586 in the vicinity thereof maintains the adhesion state while allowing the misalignment and gradually reducing the liquidity. As such, the gap formation between the metal layer 583 and the insulating layers 582 and 584 is more suppressed than when the connection between the layers constituting the heating unit 58 is performed by other units such as a thermally curable adhesive and a screw. In addition, the adhesive 586 and the insulating layer 582 or the insulating layer 584 may be films that are integrally formed from the beginning. Further, the exemplary embodiment of the invention is available, if stress conditions and temperature conditions are appropriate, even when the above-described effect of the thermoplastic resin is absent, that is, when the metal layer 581, the insulating layer 582, and the like are adhered with the thermally curable resin alone.
The exemplary embodiment of the invention has been described above. The invention is not limited to the exemplary embodiment described above and may be embodied in various manners. The examples are as follows. In addition, the respective aspects below may be combined with each other.
(1) The metal layers 581 and 585, the insulating layers 582 and 584, and the metal layer 583 are adhered in the non-heated area of the metal layer 581 in the exemplary embodiment described above. However, both the heated area and the non-heated area may be adhered. Even in this case, the metal layer and the insulating layer adhere to each other in the non-heated area, and thus the gap formation is suppressed between the heating element and the insulating layer. In addition, the adhesion is performed also in the heated area, and a force suppressing the gap formation increases.
(2) The metal layer 583 that has the heat generating portion 831 and the non-heat generating portions 832 and 833 is used in the exemplary embodiment described above. However, for example, a metal layer 583B (refer to
(3) The heating unit 58 with a curved shape is used in the exemplary embodiment described above. However, the shape of the heating unit is not limited to the shape described in the exemplary embodiment described above. For example, the heating unit may have a non-curved shape. Even in this case, the metal layer and the insulating layer are adhered in the non-heated area, and thus the gap generation is suppressed between the heating element and the insulating layer.
(4) The thermoplastic adhesive is used as the connection member that connects the metal layer and the insulating layer in the exemplary embodiment described above. However, the connection member is not limited to the connection member described in the exemplary embodiment above. For example, as illustrated in
(5) The image forming apparatus that includes the fixing unit 15 is not limited to the tandem type of the exemplary embodiment described above, and may have another configuration such as a rotary type. In addition, the image forming apparatus that includes the fixing unit 15 is not limited to the image forming apparatus that forms the image by stacking the toner images of plural colors, and may be an image forming apparatus that forms a single-colored toner image.
The foregoing description of the exemplary embodiments of the present invention has been provided for the purposes of illustration and description. It is not intended to be exhaustive or to limit the invention to the precise forms disclosed. Obviously, many modifications and variations will be apparent to practitioners skilled in the art. The embodiments were chosen and described in order to best explain the principles of the invention and its practical applications, thereby enabling others skilled in the art to understand the invention for various embodiments and with the various modifications as are suited to the particular use contemplated. It is intended that the scope of the invention be defined by the following claims and their equivalents.
Number | Date | Country | Kind |
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2013-252315 | Dec 2013 | JP | national |