The entire disclosure of Japanese Patent Application No. 2012-089635 filed on Apr. 10, 2012 is expressly incorporated by reference herein.
1. Field of the Invention
The present invention relates to a pressure-applying fixing member (herein after referred to as a “fixing pressure member”) employed in a fixing device, and to a method for producing the member. More particularly, the present invention relates to a fixing pressure member suitable for use in a fixing unit of an image-forming apparatus such as a copying machine, a facsimile machine, or a laser beam printer.
2. Background Art
Image-forming apparatuses each include an endless fixing belt (may be referred to as an “endless belt” or “endless film”) and a pressure roller which is pressed onto such a fixing member, wherein a recording medium having an unfixed toner image thereon is sandwiched by and heat-pressed between the fixing member and the pressure roller. The fixing belt of such a fixing device includes, inside thereof, a fixing pressure member which is located so as to face the pressure roller and which applies pressure from the inside of the fixing belt to the pressure roller, to thereby form a specific nip portion. Generally, such a fixing pressure member is formed of an elastic material (e.g., silicone rubber) for the purpose of attaining favorable image quality. Since such a pressure member must be slid with respect to the inner peripheral surface of the fixing belt, a lubricant (e.g., silicone oil or fluorine-containing grease) is provided between the pressure member and the inner peripheral surface of the fixing belt. In connection therewith, there has been proposed a pressure member which facilitates retention of such a lubricant between the member and the inner peripheral surface of a fixing belt, the pressure member including a pressure pad formed of only an elastic body or formed of the elastic body and a support, and a sheet-like member which is formed of a plurality of layers and provided so as to cover the pressure pad, and the pressure member optionally having, on a surface layer thereof, an embossment formed through secondary processing (see Patent Document 1).
The aforementioned sheet-like member has a three-layer structure, and must be provided so as to cover the pressure pad; i.e., the sheet-like member must be fixed to the pressure pad so as to cover it after having been formed through molding and an optional embossing process. Therefore, the sheet-like member poses a problem in that its processing and attachment require a large amount of time and cost. In addition, problems arise in that the sheet-like member, which covers the pressure pad and is partially fixed thereto, deforms in a movement direction through repeated sliding, and the friction resistance of the sheet-like member increases through continued use thereof. In the worst case, the sheet-like member may cause stoppage of the rotation of the fixing belt, or may cause shortening of the service life of the fixing device.
Patent Document 1: Japanese Patent Application Laid-Open (kokai) No. 2006-119263
In view of the foregoing, an object of the present invention is to provide a fixing pressure member which has a simple structure, which is produced through simplified production processes, which causes no problem due to continued use thereof, and which exhibits excellent durability. Another object of the present invention is to provide a method for producing the fixing pressure member.
In a first mode of the present invention attaining the aforementioned objects, there is provided a fixing pressure member employed in a fixing unit of a fixing device, the fixing pressure member comprising a sliding sheet having a sliding surface which slides with respect to the inner peripheral surface of a belt of the fixing unit, and an elastic member provided inside the sliding sheet, wherein the sliding sheet is formed of a resin fiber woven fabric, a resin fiber knitted fabric, a resin nonwoven fabric, or a resin film; the elastic member and the sliding sheet are formed through integral molding such that the elastic member is bonded to at least the inner surface of the sliding sheet opposite the sliding surface; and the sliding surface has thereon an embossment formed through an embossing process.
A second mode of the present invention is drawn to a specific embodiment of the fixing pressure member according to the first mode, wherein the interface between the elastic member and the sliding sheet has an embossment formed through the embossing process.
A third mode of the present invention is drawn to a specific embodiment of the fixing pressure member according to the first or second mode, wherein the elastic member is formed of rubber, an elastomer, foamed rubber, or a foamed elastomer.
In a fourth mode of the present invention, there is provided a method for producing a fixing pressure member employed in a fixing unit of a fixing device, the method comprising providing, on a die, a sliding sheet formed of a resin fiber woven fabric, a resin fiber knitted fabric, a resin nonwoven fabric, or a resin film, the sliding sheet having a sliding surface which slides with respect to the inner peripheral surface of a belt of the fixing unit; forming an elastic member inside the sliding sheet through integral molding so that the elastic member is bonded to at least the inner surface of the sliding sheet opposite the sliding surface; and subjecting the sliding surface of the sliding sheet to an embossing process.
The fixing pressure member of the present invention exhibits excellent durability, since the sliding sheet and the elastic member are integrally bonded together through integral molding, and the sliding surface of the sliding sheet is embossed. The fixing pressure member can be produced at low cost, since the number of processing and assembly steps are considerably reduced. Since the interface between the elastic member and the sliding sheet has an embossment formed through an embossing process, the elastic member and the sliding sheet are highly strongly bonded to each other. Therefore, even when the fixing pressure member is slid under application of high pressure, displacement of the sliding sheet does not occur. In addition, even when the fixing pressure member is slid under application of high pressure for a long period of time, since the elastic member, which is formed through integral molding, is provided on the back surface of the sliding sheet, the embossment on the sliding surface is less likely to be deformed. Thus, advantageously, the fixing pressure member can be reliably employed over a long period of time.
Various other objects, features, and many of the attendant advantages of the present invention will be readily appreciated as the same becomes better understood with reference to the following detailed description of the preferred embodiments when considered in connection with the accompanying drawings, in which:
The present invention will next be described with reference to embodiments.
The sliding sheet 11 is formed of a resin having slidability and thermal resistance, such as a fluororesin or a polyimide resin. Specifically, the sliding sheet 11 is formed of a resin fiber woven fabric, a resin fiber knitted fabric, a resin fiber nonwoven fabric, or a resin film. From the viewpoint of retention of a lubricant on the sliding surface, the sliding sheet is preferably formed of a resin fiber woven fabric, a resin fiber knitted fabric, or a resin fiber nonwoven fabric. Meanwhile, from the viewpoint of slidability, the sliding sheet is preferably formed of a resin film; in particular, a film of a fluororesin such as PFA or PTFE.
As described hereinbelow in detail, a raw material of the sliding sheet 11 is placed on a die for molding of the elastic member 12, and the sliding sheet 11 and the elastic member 12 are formed through integral molding so that the elastic member 12 is bonded to at least the surface of the sliding sheet 11 opposite the sliding surface 11a (i.e., bonded to the back surface of the sliding sheet 11). During this integral molding, the embossment 11b is formed on the sliding surface 11a. Also, an embossment 11c is formed at the interface between the sliding sheet 11 and the elastic member 12.
Particularly when the sliding sheet 11 is formed of a fluororesin film, preferably, the back surface of the sliding sheet 11 (i.e., the surface opposite the sliding surface) is subjected to a surface treatment before integral molding, for the purpose of further enhancing the bonding strength between the sliding sheet 11 and the elastic member 12. The surface treatment may be, for example, etching treatment, plasma treatment, or excimer laser treatment. When a fluororesin sheet is employed, etching treatment with ammonia is generally carried out. A primer or an adhesive may be applied to the back surface of the sliding sheet 11 before integral molding, and this application may be carried out with or without the surface treatment.
The elastic member 12 is formed of thermally resistant rubber, elastomer, foamed rubber, or foamed elastomer; for example, silicone rubber or elastomer, or fluororubber. Preferably, the heat capacity of the elastic member 12 is reduced for preventing deprivation of heat from a fixing unit. From this viewpoint, the elastic member 12 is preferably formed of foamed rubber or elastomer.
For integral molding of the sliding sheet 11 and the elastic member 12, a raw material of the sliding sheet 11 is placed on a die, and the elastic member 12 is formed through molding with the die. Formation of an embossment on the sliding surface 11a of the sliding sheet 11 may be carried out by means of a die having thereon an embossment, or, for example, a metal mesh placed on the die employed.
The support 13 may be a member formed of, for example, a metal or a heat-resistant resin. The support 13 may be bonded to the elastic member 12 through integral molding of the support 13 and the elastic member 12. Alternatively, the support 13 may be bonded to the elastic member 12 by means of an adhesive after molding of the elastic member 12.
The support 13 may be omitted, and the fixing pressure member may be produced by providing the sliding sheet 11 only on the elastic member 12.
As shown in
As shown in
A test apparatus as shown in
There was employed the fixing belt 33 including an electroformed nickel substrate (inner diameter: 30 mm, thickness: 40 μm), a silicone rubber elastic layer (thickness: 100 μm) provided on the substrate, and a PFA tube (thickness: 30 μm) provided on the layer. There was employed the pressure roller 34 including a silicone rubber elastic layer (outer diameter: 30 mm, thickness: 3 mm), and a PFA tube (thickness: 30 μm) provided outside the layer. A halogen heater was employed as the heater 32.
A fixing pressure member produced through the method described in Example 1 (sliding surface width: 10 mm, thickness: 3 mm) was employed as the fixing pressure member 31.
For comparison, a fixing pressure member having the same size as in Example 1 was produced by fixing a fluororesin fabric (product of Gunze Limited) to a pressure member prepared through bonding of silicone rubber to an SUS plate so that the pressure member was bonded to the inner surface of the fabric opposite the sliding surface. The thus-produced fixing pressure member was employed as the fixing pressure member 31, and compared with that of the Example.
The test was carried out as follows. Specifically, fluorine-containing grease was applied to the sliding surface of a fixing pressure member, and the fixing pressure member was placed inside the fixing belt 33. The pressure roller 34 was pressed against the fixing belt 33 (percent compression: about 30%), and the pressure roller 34 was rotated at a linear velocity of 120 mm/sec. While the pressure roller 34 was rotated, temperature was controlled at 150° C. by means of the heater 32.
One hour later, the operation was stopped, and the sliding surface of the sheet was visually observed for determining whether or not deformation occurred. No deformation was observed in the fixing pressure member of the Example. In contrast, in the comparative fixing pressure member, the fluororesin fabric was deformed in a movement direction.
The fixing pressure member of the Example was further subjected to the aforementioned test (operation) for 300 hours. However, no deformation was observed in the sliding surface of the sheet.
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