JP3929581B2 - Electrophotographic fixing roll and fixing device - Google Patents

Description

表１から、外表面がＳｉゴムのロールに比べて、外表面がフッ素ゴムのロールの方が耐摩耗性が高い。
【００４１】
【発明の効果】
以上説明したように、本発明の炭素繊維強化金属コアロールの少なくとも外表面に、フッ素含有樹脂及び／またはフッ素ゴムからなる離型層を設けた定着ロール及びそれを備えた定着装置は、コアロールの厚みを減らし熱容量を減らしながらも、強度を維持できるので、ウオームアップ加熱に要するエネルギー消費を減らすことができ、また、オフセットを防止することができる。また、本発明は、ロールとベルト両者のくみ合わせによる各種定着装置に対しても応用可能である。また、中空ロールのフランジ接合部分を除く部分で炭素繊維の織物状シートが金属と一体的に形成され、フランジ接合部分が金属のみからなるので、この金属部分の内面加工が容易であるため、定着ロールの製造を簡便に行なうことができる。
【図面の簡単な説明】
【図１】本発明の定着ロールの好ましい一実施の形態を示す概略的断面図である。
【図２】本発明の定着装置の好ましい一実施の形態を示す概略的構成図である。
【図３】本発明の定着装置の好ましい他の実施の形態を示す概略的構成図である。
【図４】本発明の定着装置の好ましい更に他の実施の形態を示す概略的構成図である。
【図５】本発明の定着装置の好ましい更に他の実施の形態を示す概略的構成図である。
【図６】本発明の定着装置の好ましい更に他の実施の形態を示す概略的構成図である。
【符号の説明】
１ 炭素繊維強化アルミコアロール
２ シリコーンゴム弾性体層
３ アルミ層
４ 加熱源
５ フランジ
６ 炭素繊維強化アルミ層
７ フッ素ゴム離型層
２１ 加熱ロール
２５ 加圧ロール
４１ 加熱ロール
４２ 加圧ロール
５１ 加熱ロール
５２ 加圧ロール
５４ 搬送ベルト
６１ 耐熱性ベルト
６２ 加圧ロール
６３ 加圧部材
６５ 加圧ロール
８１ 離型層
８２ 炭素繊維強化コアロール
８３ 押圧部材
８５ 離型層
８６ 炭素繊維強化コアロール
８７ 押圧部材[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a fixing roll used in a fixing device of an image forming apparatus such as an electrophotographic copying apparatus and an electrophotographic printer using powder toner. Furthermore, the present invention relates to a fixing device, and more particularly to a fixing device that can save energy by reducing the size of the device and greatly shortening the warm-up time.
[0002]
[Prior art]
Conventionally, in a copying machine using an electrophotographic process, it is necessary to fix an unfixed toner image formed on a recording sheet to make a permanent image. As a fixing method thereof, a solvent fixing method, a pressure fixing method, and A heat fixing method is known.
However, the solvent fixing method has the disadvantage that solvent vapors diverge and there are many odor and hygiene problems. On the other hand, the pressure fixing method is poor in fixing property and pressure sensitive compared to other fixing methods. Toner has the disadvantage that it is expensive, and both are not widely used yet.
For this reason, for fixing an unfixed toner image, a heat fixing method in which toner is generally melted by heating and fused onto a recording sheet is widely employed.
[0003]
As this heat fixing device, a cylindrical cored bar is provided with a heater amplifier and a heat-resistant release layer is formed on the outer peripheral surface thereof, and is arranged in pressure contact with the fixing roll. A heat-fixing roll type is known which is composed of a pressure roll having a heat-resistant elastic layer formed on the outer peripheral surface, and is fixed by inserting a sheet on which an unfixed toner image is formed between these rolls. This is the most efficient because it has higher thermal efficiency compared to other hot fixing methods such as hot air fixing method and oven fixing method, and has low power and high speed, and there is less risk of fire due to paper jam. Widely used.
[0004]
By the way, in a conventional fixing roll type fixing device, the time required to raise the surface temperature of the fixing roll from room temperature to a predetermined set temperature (hereinafter referred to as warm-up time) is as long as 1 to 10 minutes. I needed it. The warm-up time is simply determined by the heat capacity of the roll and the input power.
That is, if the roll heat capacity is small and the input power is large, the warm-up time can be shortened. However, the roll heat capacity is limited by roll rigidity, and the input power has limitations due to the power consumption of the machine. Therefore, in general, the power that can be input exclusively for fixing is about 300 W to 1200 W. In order to shorten the warm-up within this range, it is most effective to reduce the roll heat capacity. However, when the roll diameter and the roll core thickness are decreased to reduce the roll heat capacity, the roll strength also tends to be weakened.
Incidentally, the roll heat capacity is proportional to the square of the roll diameter, whereas the roll rigidity is proportional to the fourth power of the roll diameter. For this reason, when the roll diameter is equal to or less than a certain roll diameter, the roll rigidity is suddenly reduced, the roll is greatly bent, and a load necessary for fixing cannot be obtained.
[0005]
In order to solve these problems, various roll strength reinforcement techniques and various roll sag correction techniques have been proposed. For example, Japanese Patent Application Laid-Open Nos. 59-30571 and 59-128665 disclose one or two or more pieces that support a sleeve via a thermal insulator inside a sleeve constituted by a thin plate having a small heat capacity. A roll strength reinforcement technique has been proposed in which an inner casing is arranged between both supports so as to be flexible. JP-A-56-60471 discloses a disk that is fitted to a pressure shaft as a fulcrum member, and has upper and lower hollows. A roll squeezing correction technique has been proposed in which this pressure shaft is placed in a pipe roll pair, a load is applied to both ends and the pressure section shaft is bent to obtain a uniform pressure on the hollow pipe roll pair. Yes. In addition, JP-A-4-44074, JP-A-4-44075, and JP-A-4-372974 disclose a uniform heating and pressurizing part by disposing a heating and pressing member fixed inside an endless film or belt. Japanese Unexamined Patent Publication No. 6-43775 discloses a technique to be obtained, in which a pressure member is pressed at a constant pressure against a hollow heat roll containing a resistance heating element therein. It is disclosed whether it has a heat transfer plate in which arc-shaped convex portions corresponding to the surface are formed, and heat is structured to heat the heat roll via the heat transfer plate. None of these techniques improve the strength of the metal roll itself, so there is a short life problem due to metal fatigue in the long term.
[0006]
On the other hand, a roll and a fixing device are disclosed in which the roll has a mechanical strength increased by a reinforcing fiber such as carbon fiber. For example, Japanese Utility Model Laid-Open No. 61-024765 discloses a fixing device in which an unfixed image on a recording sheet is pressure-fixed at a nip portion between a pair of adjacently rotating rolls, and at least one of the rolls is made of carbon. A technique having a fiber-reinforced surface layer is disclosed, and the carbon fiber-reinforced surface layer is obtained by dispersing and reinforcing carbon fibers in a resin matrix. However, the pressure fixing toner used in this fixing device is mainly a wax or a microcapsule toner in which a mixture of resin and oil that is liquid at room temperature is covered with a resin layer that is solid at room temperature. In particular, special toners such as these are required and are not often used.
[0007]
In addition, Japanese Utility Model Publication No. 58-48684 discloses an exothermic structure in which a roll body having insulating properties and heat resistance and a carbon fiber are integrally formed on the roll body in a certain direction using a polymer binder. A heat fixing roll comprising a body and a releasable layer covering the heating element is disclosed.
Since the heat fixing roll also strengthens the resin layer, it is difficult to obtain mechanical strength higher than that of the metal roll, and the fixing roll core cannot be thinned even when used in the above-described heat fixing apparatus. Also, the thermal conductivity is worse than that of metal, and the heating time is not shortened.
[0008]
Further, in JP-A-6-207614, in a carbon fiber reinforced resin roll formed by integrally forming a resin film on the surface, the secondary dislocation point (Tg) of the resin constituting the carbon fiber reinforced resin is less than. Fluorine / silicone-containing polymer obtained by copolymerization of copolymerizable fluorine-containing monomer that can be baked and cured at temperature, silicon macromonomer, and other copolymerizable vinyl monomers is integrally coated on the surface. A carbon fiber reinforced resin roll having good ink releasability, characterized by being formed, is disclosed. Since this carbon fiber reinforced resin roll also strengthens the resin layer, it is difficult to obtain a mechanical strength higher than that of the metal roll, and the fixing roll cannot be thinned even when used in the above-described heat fixing apparatus. In the above example, since the resin is a roll reinforced with carbon fiber, the resin itself needs to have a heat resistant temperature, and the resin used is limited to a thermosetting heat resistant resin. Get higher.
[0009]
As a roll in which a metal is reinforced with carbon fiber, Japanese Patent Application Laid-Open No. 7-206241 discloses that the matrix metal is formed on the surface of a metal pipe or metal solid shaft whose matrix metal is reinforced with graphitized carbon fiber. A fiber reinforced metal roll in which coating layers of different materials are formed is disclosed. This fiber-reinforced metal roll has the advantage that it is easy to achieve mechanical strength higher than that of the metal core roll and has sufficient heat resistance. For this reason, when it is used in the above-mentioned heat fixing apparatus, the fixing roll can be thinned and the heating time can be shortened.
However, since these rolls are used in contact rolls, transport rolls, nip rolls, and the like used in industries such as high-speed printing machines and film coating machines, toner offset tends to occur when used in the above-described heat fixing apparatus.
[0010]
As described above, in the prior art, there is no fixing roll that can sufficiently reduce the heat capacity of the fixing roll and prevent the occurrence of offset by reducing the thickness of the roll while increasing the mechanical strength of the roll material. It was.
[0011]
[Problems to be solved by the invention]
The first object of the present invention, in view of the above-mentioned problems of the prior art, can have equal or higher mechanical strength even if the roll thickness is reduced compared to conventional aluminum or iron metal rolls, Another object of the present invention is to provide an electrophotographic fixing roll capable of preventing toner offset.
A second object of the present invention is to provide a fixing roller having at least one of a heating roll and a pressure roll in order to form a fixing nip region through which an unfixed toner image passes. It is an object of the present invention to provide a fixing device for electrophotography with reduced power consumption and reduced heating time and low power consumption.
[0012]
  The fixing roll for electrophotography according to the present invention is a hollow carbon fiber reinforced metal core roll formed by integrally forming a matrix metal and a woven sheet of graphitized carbon fiber.Both ends in the roll axis direction are made of a matrix metal, and at least the inner peripheral surface of the both end portions is cut and joined to the outer peripheral surface of the flange via an adhesive,An electrophotographic fixing roll, wherein a release layer comprising a fluorine-containing resin and / or fluorine rubber is provided on at least the outer surface of the hollow carbon fiber reinforced metal core roll.
  The fixing device according to the present invention includes (1) an apparatus having a heating roll and a pressure roll in order to form a fixing nip region through which an unfixed toner image passes. And (2) a heating roll, a pressure belt that presses the heating roll, and a pressure roll that presses the pressure belt from the back. And a heating and pressing type fixing device in which an unfixed toner image is passed through a nip region formed by the pressure belt and fixed by heat and pressure, and the heating roll is configured as the fixing roll for electrophotography. .
[0013]
  Hereinafter, preferred embodiments of the present invention will be described.
  The fixing roll of the present invention is a hollow carbon fiber reinforced metal core roll formed by integrally forming a matrix metal and a woven sheet of graphitized carbon fiber.Both end portions in the roll axial direction are made of a matrix metal, and at least the inner peripheral surfaces of the both end portions are cut and joined to the outer peripheral surface of the flange via an adhesive, and at least the outer periphery of the hollow carbon fiber reinforced metal core roll. A release layer made of fluorine-containing resin and / or fluorine rubber is provided on the surface.
[0014]
The graphitized carbon fiber reinforced metal core roll is formed by winding a woven sheet of graphitized carbon fiber around a core roll such as carbon steel and integrating them by a known method. For example, a high pressure casting method in which a molten metal matrix mold is cast by casting at a high pressure, or a squeeze caster in which a woven sheet of graphitized carbon fiber is placed in a mold and then poured into a molten metal matrix mold at a high pressure. Metal and graphitized carbon fiber fabrics are integrally formed by a low-pressure plasma deposition method, in which a graphitized carbon fiber fabric sheet is wound around a coating method or core roll, etc. can do. Here, aluminum, aluminum alloy, iron, copper, magnesium or magnesium alloy, titanium or titanium alloy, etc. can be used for the metal matrix. Among these metals, iron, copper and the like are preferably used when workability and heat resistance are important. Aluminum and aluminum alloys having a relatively low melting point are preferable from the viewpoint of easy formation of a graphitized carbon fiber fabric, and alloys of aluminum and titanium or magnesium, iron, and the like are preferable from the viewpoint of increasing mechanical strength. Therefore, aluminum, aluminum alloy, and iron are preferable in consideration of workability and cost.
[0015]
Usually, as reinforcing fiber, in addition to graphitized carbon fiber, Roron, SiC, Al₂O_3,Be, W, etc. are mentioned, but if the outer diameter of the fiber is thick and the metal is thin, the thickness will be uneven. Therefore, in the present invention, a graphitized carbon fiber having a small outer diameter is used. . A graphitized carbon fiber woven sheet is made by weaving yarns that bundle about 1000 to 20000 graphitized carbon fibers with a diameter of 5 to 10μm, which are carbonized and fired at high temperature (2000 ° C) to remove impurities. A sheet is preferable. The woven fabric sheet of graphitized carbon fiber is preferably a woven fabric of 1000 units for ease of molding operation. Specifically, woven sheets such as Mitsubishi Rayon Pyrofil and Toray Trading Card can be used. The directionality of the fibers is not necessarily important, and the important point is that the carbon fibers are arranged in a certain direction. Therefore, the direction of the carbon fiber may be a direction orthogonal to the core roll, or may be a direction of skewing.
[0016]
  The weight ratio of the graphitized carbon fiber in the graphitized carbon fiber reinforced metal roll is preferably 10 to 70 wt%, more preferably 30 to 50 wt%. If the weight ratio is less than 10 wt%, the mechanical strength cannot be increased, and if the weight ratio exceeds 70 wt%, the metal matrix that bonds between the carbon fibers is reduced and the binding force between the carbon fibers is weakened. This is because damage such as cracks is likely to occur in the roll due to mechanical impact.
The graphitized carbon fiber reinforced metal roll produced by the above-mentioned method is surface-processed with a high-speed rotary polishing roll etc. in order to produce a roundness of the outer diameter with a size close to the finished size, and the inner diameter of the flange joint at the roll end. The same processing is performed to obtain the roundness of. Thus, graphitized carbon fiber reinforced metal rollButA fixed core roll is produced.
[0017]
  At this time, since the carbon fiber is hard, it is impossible to cut the carbon fiber by processing to make the surface smooth, when the core roll thickness is as thin as 0.2 to 3.0 mm, and a large load is applied to the roll by surface processing such as polishing processing. Because it is difficult. Since the outer surface of the roll is provided with a release layer with lower surface energy, smoothness is not so necessary, but the inner surface of the roll at the flange joint at the end of the roll increases the strength of the flange joint.RutaTherefore, it is not preferable that the carbon fibers remain after processing and have no smoothness. Accordingly, it is preferable that the carbon fiber woven sheet is formed integrally with the metal in the portion excluding the flange joint portion at the end of the hollow roll, and the inner surface processing becomes easy because the flange joint portion is made of only the metal.
[0018]
The release layer formed on the surface of the hollow carbon fiber reinforced metal core roll is made of a fluorine-containing resin and / or fluorine. This release layer can be formed by various known methods such as spray coating, coating, and tubing after applying a heat resistant primer to the surface of the carbon fiber reinforced metal core roll. The surface energy of the release layer is preferably about 25 dyn / cm or less, and it is reported that fluorinated carbon, perfluorocarbon, etc. are 6 dyn / cm 2, and the release layer contains these carbons. There may be. When forming a fluorine-containing resin layer, it is preferable that the thickness is thin so as not to deteriorate the thermal conductivity. Even if wear or scratches occur due to long-term use, the fluorine-containing resin layer remains and the surface of the fixing core roll is exposed. In order not to become thick, the thicker one is preferable. From these points, the release layer is usually preferably about 10 to 40 μm.
[0019]
Fluorine-containing resin layer consists of 4 fluoroethylene resin (PTFE resin), 4 fluoroethylene-perfluoroalkoxyethylene copolymer (PFA resin), 4 fluoroethylene-6 fluoroethylenepropylene copolymer (PFE resin) ) Fluorocarbon resin, carbon particles, silica particles, etc., mainly composed of fluororesins with excellent releasability and heat resistance, such as amorphous cyclic fluororesins. A mixture of these inorganic particles can also be used. These fluororesin mixtures are made into a dilute solution with electrostatic coating or a special solvent, coated by spray coating, roll coating, dipping, spinning, etc., and baked and cured before use. Alternatively, a heat-shrinkable tetrafluoroethylene-perfluoroalkoxyethylene copolymer (PFA resin) tube is heat-shrinked to obtain a fixing roll having a fluorine-containing resin layer formed on the surface of a carbon fiber reinforced metal core roll. You can also.
[0020]
When using fluororubber, a general purpose one can be used. As the fluororubber, vinylidene fluoride rubber, tetrafluoroethylene / propylene rubber, tetrafluoroethylene / perfluoromethyl vinyl ether rubber, phosphazene rubber, fluoropolyether, and other fluororubbers can be used. These may be used alone or in combination of two or more. These rubbers can use various inorganic or organic fillers.
[0021]
Inorganic fillers include carbon black, titanium oxide, silica, silicon carbide, talc, mica, kaolin, iron oxide, calcium carbonate, calcium silicate, magnesium oxide, graphite, silicon nitride, boron nitride, iron oxide, aluminum oxide, Examples thereof include magnesium carbonate. As the organic filler, polyimide, polyamideimide, polyether sulfone, polyphenylene sulfide, and the like can be used.
In addition, silicone rubber, fluororubber, fluorosilicone rubber, or the like can be formed as an elastic layer under the release layer.
[0022]
FIG. 1 is a cross-sectional view showing a preferred embodiment of the fixing roll for electrophotography of the present invention, in which 1 is a carbon fiber reinforced aluminum core roll, 2 is a carbon fiber reinforced aluminum layer, 3 is an aluminum layer, 4 Is a heat source, 5 is a flange, 6 is a silicone rubber layer, and 7 is a fluoro rubber release layer.
[0023]
Next, a preferred embodiment of the electrophotographic fixing device of the present invention will be described with reference to the drawings.
FIG. 2 is a schematic configuration diagram showing a preferred embodiment of the electrophotographic fixing device of the present invention. This fixing device is suitable for obtaining a color image, and is mainly composed of a heating roll 21 configured as the above-described fixing roll for electrophotography and a pressure roll 25 opposed to the pressure roller. Therefore, the fixing roll 21 includes a heater lamp 29 inside a hollow carbon fiber reinforced metal core roll 22 formed integrally with a matrix metal and a woven sheet of graphitized carbon fiber, and the outer periphery of the carbon fiber reinforced metal core roll 22 is provided. An elastic layer 23a and a heat-resistant low surface energy release layer 23b are formed on the surface. The pressure roll 25 has a heat-resistant elastic layer 27 formed on the outer peripheral surface of the cylindrical cored bar 26, and a surface coating layer 28 is formed on the heat-resistant elastic layer 27.
In FIG. 1, 30 is a heating source, 31 is a release agent coating device, 32 is an inlet chute, and 33 is an outlet chute.
[0024]
In this fixing device, a fixing nip region is formed by the heating roll 21 and the pressure roll 25. At this time, the pressure of the heating roll 21 and the pressure roll 25 is 1 to 15 kg / cm.², Preferably 3-10Kg / cm²Is applied to the separation claw for preventing the sheet from being wound around the fixing roll, or to the fixing roll, and the fixing is performed by inserting the sheet 34 on which the unfixed toner image 35 is formed. A cleaning device for cleaning the attached offset toner may be arranged. The pressure roll 25 can also be a roll having the same configuration as the heating roll.
[0025]
FIG. 3 is a schematic diagram showing another preferred embodiment of the fixing device of the present invention, and this device is a fixing device suitable for obtaining a black and white image.
In FIG. 3, 41 is a heating roll, 42 is a pressure roll, 43 is an aluminum core roll, 44 is a silicone rubber elastic layer, 45 is a separation claw, 46 is a cleaning web, 47 is a temperature sensor, 48 is an unfixed toner image, 49 Indicates paper.
In this fixing device, since the heating roll 41 fixes a toner image having elasticity, the roll surface preferably has a certain degree of hardness. Therefore, an elastic body layer made of silicone rubber is not necessarily required. Therefore, the heating roll 41 may have a roll configuration having a release layer 41b made of a fluorine-based resin or fluorine-based rubber on the outer peripheral surface of the carbon fiber reinforced metal core roll 41a, and the pressure roll 42 side is made of an aluminum core roll 43 with silicone rubber or the like. You may have the elastic body layer 44, and you may have elastic body layers, such as a silicone rubber, on the carbon fiber reinforced metal core roll outer peripheral surface.
[0026]
FIG. 4 is a schematic diagram showing still another preferred embodiment of the fixing device of the present invention. In FIG. 4, 51 is a heating roll, 52 is a pressure roll, 53 is a tension control roll, 54 is a conveyor belt, and 55 is a heating lamp.
The heating roll 51 is composed of a roll having an elastic body layer 51b made of silicone rubber and a release layer 51c made of fluorine-based resin or fluorine-based rubber on the outer peripheral surface of the carbon fiber reinforced metal core roll 51a.
[0027]
FIG. 5 is a schematic diagram showing still another preferred embodiment of the fixing device of the present invention, and shows a thermal transfer belt type fixing device. In FIG. 5, reference numeral 61 designates a heat-resistant belt such as polyimide as a support, and a low surface energy layer such as PFA is formed thereon as a release layer, and 62 and 65 are pressure rolls. Reference numeral 63 denotes a pressurizing member in the pressurizing roll 62 and having a tip 63a made of a low friction member such as Teflon. Reference numeral 64 is a heating lamp, 67 is a core roll, 66 is a silicone rubber layer, 68 is a peeling claw, 69 is an inlet chute, 70 is unfixed toner, and 71 is paper.
The pressure roll 62 has a rubber layer made of fluoro rubber having a thickness of 20 μm on the surface of the carbon fiber reinforced core roll, and the pressure roll 65 is an elastic layer made of a silicone rubber layer on the surface of the carbon fiber reinforced core roll. have.
[0028]
FIG. 6 is a schematic diagram showing still another preferred embodiment of the fixing device of the present invention, and shows a roll type fixing device having an intermediate thickness between a belt and a roll. 82 and 86 are carbon fiber reinforced core rolls, on which release layers 81 and 85 coated with fluororubber, fluororesin or the like are formed. Reference numerals 83 and 87 denote pressure members 83a and 87a made of a low friction member such as Teflon and located at the tip portion. Reference numeral 84 denotes a heating lamp, 88 denotes a peeling claw, 89 denotes an inlet sisch, 90 denotes unfixed toner, and 91 denotes paper.
[0029]
(Function)
Since the fixing roll of the present invention is formed of a carbon fiber reinforced metal core roll, the mechanical strength such as the bending elastic modulus is improved as compared with the aluminum and iron rolls used in the conventional heat fixing apparatus. Axial roll deflection and circumferential roll distortion even at the same load applied to both endsButSince it becomes small, the thickness can be set thin. By reducing the thickness, the heat capacity of the fixing roll can be reduced, and the warm-up heating time can be shortened. This makes it possible to consume less power than the conventional heat fixing apparatus.
In addition, the carbon fiber woven sheet is formed integrally with the metal in the portion excluding the flange joint portion of the hollow roll, and the flange joint portion is made of only metal, so that the inner surface processing of the metal portion is facilitated. The fixing roll can be easily manufactured.
[0030]
The heat fixing device using the fixing roll of the present invention is effective especially in a high-speed image forming apparatus because the amount of power consumption is reduced. This is due to the circumstances described below. The mechanical strength such as flexural elasticity required for the fixing roll is largely determined by the diameter of the fixing roll and the load applied to the fixing roll. In a normal heat fixing device, the diameter of the fixing roll is 15 to 100 mm, and the load applied to the fixing roll is in the range of 3 to 300 kgf. These values vary greatly depending on the copying speed of the image forming apparatus, and also slightly differ depending on the maximum usable paper width, toner material, and the like. In general, as the speed of the image forming apparatus increases, the fixing roll diameter is increased so that the Dwell Time, which is the passage time of the fixing nip portion of the paper, does not become too short, and the force for attaching the toner to the paper is increased. Therefore, it is necessary to increase the load applied to the fixing roll and increase the pressure in the fixing nip portion. When the diameter of the fixing roll and the load applied to the fixing roll are increased, it is difficult to reduce the thickness of the roll unless the mechanical strength such as bending elasticity required for the fixing core roll is increased. In addition, the warm-up heating time for setting the fixing roll surface at a fixed temperature is determined by the thickness of the core roll if the same material is used. Therefore, the warm-up heating time is shortened as the core roll is thinner. Come. Also in the case of the carbon fiber reinforced metal roll of the present invention, since it is not much different from the thermal conductivity of the matrix metal, the warm-up heating time can be shortened by reducing the thickness of the core roll.
[0031]
If the image forming apparatus is slow, for example, if the speed is about 80 mm / s or less, the fixing roll diameter is 15 to 20 mm, the load is 10 kgf or less, and the pressure in the fixing nip is 1 kgf / cm.²It can be set within a range. In this case, the fixing roll is a conventional aluminum roll, the core roll thickness can be set to 1.5 mm or less, and the fixing temperature can be set at a waiting time of about 60 seconds or less. Power consumption is low.
[0032]
However, when the speed of the image forming apparatus is 300 mm / s or higher, the load applied to the fixing roll is about 100 to 300 kgf, and the pressure is 5 to 10 kgf / cm as the pressure of the fixing nip portion.²It is set to a range of about. In this case, the diameter of the fixing core roll needs to be about 30 mm or more, and if it is a conventional aluminum roll, it must be set to a thickness of about 4 mm or more, and it takes about 4 minutes to set the fixing roll surface at a settable temperature. The above warm-up heating time is required. For this reason, the high-speed machine is set to the standby mode by heating the fixing roll to a predetermined temperature even when normal image formation is not performed. For this reason, the high-speed machine consumes extra power even when normal image formation is not performed.
[0033]
Therefore, the heat fixing device using the fixing roll of the present invention is effective because the amount of reduction in power consumption becomes large, particularly in a high-speed image forming apparatus.
In addition, since the surface of the fixing roll of the present invention is provided with a low surface energy release layer excellent in releasability of toner composed of fluorine-containing resin and / or fluorine rubber, a conventional heat fixing toner is used. However, no offset occurs.
[0034]
【Example】
Example 1
Next, an embodiment of the present invention will be described.
(1) Creating core roles
The manufacturing method of a core roll is demonstrated based on FIG. The production method of the fixing roll is as follows. First, a ribbon-like carbon fiber sheet in which 6000 pieces of carbon fibers with a diameter of 5 to 7 microns are aligned in a bundle around a carbon steel core (outer diameter 37.0 mm, length 400 mm). (CO6644B, plain weave, trading card, manufactured by Toray Industries, Inc.) Wrapping around the core 15mm (part of the aluminum layer 3 in Fig. 1) around the core, spirally 10 times (about 2mm thick) in the circumferential direction, This was set in a mold having an outer diameter of 44.05 mm and a length of 400 mm, and then cast by injecting and pressing a molten aluminum to produce a solid shaft having an outer diameter of 44.0 mm and a length of 400 mm. The fiber content was calculated to be about 33% by weight. The core was then decentered to produce a carbon fiber reinforced aluminum core 1 sleeve having an inner diameter of 37.0 mm, an outer diameter of 44.05 mm, a thickness of 3.5 mm and a length of 370 mm. A portion of the aluminum layer 3 with both ends of 15 mm was cut to obtain a roundness of the inner diameter, and this portion was mirror-finished with powdered carbon steel. Thereafter, a flange 5 made of carbon steel S45C having a wall thickness of 5 mm and an outer diameter of 37.0 mm was joined to both end portions of the core roll with an adhesive to produce a carbon fiber reinforced aluminum core roll.
[0035]
(2) Strength comparison
This reinforced core roll was compared with an unreinforced aluminum core roll having the same dimensions and made of the same material in a bending rigidity test. Flexural modulus of unreinforced aluminum core roll is 5000Kg / mm²Specific elasticity is 1.8 × 10^ThreeWhereas the above-mentioned reinforced core roll has a flexural modulus of 27000 kg / mm², Specific elasticity is 10 × 10^Threemm, and it was found that both the flexural modulus and specific elasticity were 5 times.
[0036]
(3) Creating a fixing roll
Thereafter, the carbon fiber reinforced hollow roll was polished with a carbon steel brush roll so that the outer diameter was 44.0 mm, and the roundness of the outer diameter was obtained to prepare for coating the silicone rubber underlayer. Silicone rubber as the elastic layer was coated with HTV silicone rubber having a rubber hardness of 55 degrees to a thickness of 3 mm to form a base roll. In addition, a primer for fluororubber was applied to the surface, and binary peroxide-based fluororubber G-802 (Daikin Kogyo Co., Ltd.) was formed to a thickness of 40 μm. The elastic layer was silicon rubber and the release layer Made a heating roll made of fluoro rubber. The surface was polished and polished to obtain a fixing roll having an outer diameter of about 50.0 mm, an inner diameter of 44 mm, and a length of 400 mm.
[0037]
(4) Creation of pressure roll
A pressure roll was prepared in exactly the same manner as the fixing roll except that the thickness of the silicone rubber elastic layer on the core roll was 1 mm.
(5) Warming-a time measurement and copy test using actual fixing device
The fixing roll and the pressure roll were installed in the fixing apparatus shown in FIG. 2, and the warm-up time measurement and the copy test were performed. The copy discharge speed is 150mm / sec, the load is 130Kgf, the nip width created by the two rolls is 6.0mm, the power of the halogen lamp heating means of the fixing roll and pressure roll is 650W and 525W, and the set temperature is 155 ℃ It was. First, the warm-up time from room temperature 20 ° C to the set temperature was 310 seconds, which was greatly reduced. Even when the nip was set to 6.0 mm, no abnormal dent or nip shape was observed at the end, and the toner could be fixed without any problem even when the unfixed toner image was actually conveyed.
[0038]
Comparative Example 1
(1) Creating core roles
A core roll of 7.5 mm (inner diameter: 29 mm) was produced with the same aluminum material as in Example 1, the same outer diameter, only the thickness being different.
(2) Strength comparison
A non-reinforced aluminum core roll and a reinforced aluminum core roll having different thicknesses were subjected to a comparative test in a bending rigidity test. Flexural modulus of unreinforced core roll with a thickness of 7.5mm is 21000Kg / mm²Specific elasticity is 7.8 × 10^ThreeWhereas the thickness was 3.5 mm, the reinforced aluminum core roll with a thickness of 3.5 mm had a flexural modulus of 27000 kg / mm.², Specific elasticity is 10 × 10^ThreeIt was found that the bending elastic modulus and specific elasticity were about 1.3 times.
(3) Preparation of fixing roll and pressure roll
In exactly the same manner as in Example 1, a silicone rubber elastic layer and a fluororubber release layer were sequentially formed on the surface of the core roll to prepare a fixing roll and a pressure roll.
(5) Warming-a time measurement and copy test using actual fixing device
The fixing roll and the pressure roll were installed in the fixing apparatus shown in FIG. 2, and the warm-up time measurement and the copy test were performed. Various conditions were the same as in Example 1. Even when the nip was set to 6.0 mm, no abnormal dent or nip shape was observed at the end, and even if an unfixed toner image was actually conveyed, it could be fixed without any problems. However, the warm-up time was significantly longer at 420 seconds.
[0039]
Next, in the fixing device having the configuration shown in FIG. 2, the heating roll is provided with a layer of Si rubber (3 mm) having an HTV hardness of 60 ° on the core, and an HTV Si rubber containing 5% free oil on the outer surface. A roll (1) having a thickness of 50 μm and a heating roll provided with a layer of Si rubber (3 mm) having an HTV hardness of 60 ° on the core and a roll (2) having a fluororubber of 40 μm formed on the outer surface thereof. Each was fabricated and subjected to a comparative test of wear resistance. The speed of m / c was adjusted to 100 mm / sec, and the chip width was adjusted to 6.0 mm. The toner used was an Acolor cyan toner with a toner amount of 0.7 mg / cm.²The paper used was Fuji Xerox Co., Ltd. J paper. The set temperature was 160 ° C., the paper was fed longitudinally, the part that touched the paper and the part that did not touch were made in the width of the roll, and the degree of wear of each was measured.
As the release agent, Acola Fuser oil was supplied in an amount of 10 μl / A4 copy. As a result, the level difference (due to paper wear) between the paper passing portion and the non-paper passing portion on the roll surface after 200000 copies was as follows.
[0040]
[Table 1]

From Table 1, the outer surface of the fluoro rubber roll has higher wear resistance than the roll of Si rubber.
[0041]
【The invention's effect】
  As described above, the fixing roll provided with a release layer made of fluorine-containing resin and / or fluorine rubber on at least the outer surface of the carbon fiber reinforced metal core roll of the present invention, and the fixing device provided with the fixing roll have the thickness of the core roll. Since the strength can be maintained while reducing the heat capacity and the heat capacity, the energy consumption required for warm-up heating can be reduced, and offset can be prevented. The present invention can also be applied to various fixing devices by combining both a roll and a belt. Also,Since the carbon fiber woven sheet is integrally formed with the metal except for the flange joint portion of the hollow roll, and the flange joint portion is made only of metal, the inner surface of this metal portion is easy to process. Manufacture can be performed easily.
[Brief description of the drawings]
FIG. 1 is a schematic cross-sectional view showing a preferred embodiment of a fixing roll of the present invention.
FIG. 2 is a schematic configuration diagram showing a preferred embodiment of a fixing device of the present invention.
FIG. 3 is a schematic configuration diagram showing another preferred embodiment of the fixing device of the present invention.
FIG. 4 is a schematic configuration diagram showing still another preferred embodiment of the fixing device of the present invention.
FIG. 5 is a schematic configuration diagram showing still another preferred embodiment of the fixing device of the present invention.
FIG. 6 is a schematic configuration diagram showing still another preferred embodiment of the fixing device of the present invention.
[Explanation of symbols]
1 Carbon fiber reinforced aluminum core roll
2 Silicone rubber elastic layer
3 Aluminum layer
4 Heating source
5 Flange
6 Carbon fiber reinforced aluminum layer
7 Fluoro rubber release layer
21 Heating roll
25 Pressure roll
41 Heating roll
42 Pressure roll
51 Heating roll
52 Pressure roll
54 Conveyor belt
61 Heat resistant belt
62 Pressure roll
63 Pressure member
65 Pressure roll
81 Release layer
82 Carbon fiber reinforced core roll
83 Pressing member
85 Release layer
86 Carbon fiber reinforced core roll
87 Pressing member

Claims (7)

Both ends in the roll axis direction of a hollow carbon fiber reinforced metal core roll integrally formed with a matrix metal and a woven sheet of graphitized carbon fiber are made of matrix metal, and at least the inner peripheral surface of the both ends is cut. It is joined to the outer peripheral surface of the flange via an adhesive, and a release layer made of fluorine-containing resin and / or fluorine rubber is provided on at least the outer surface of the hollow carbon fiber reinforced metal core roll. A fixing roll for electrophotography.   The fixing roll for electrophotography according to claim 1, wherein the matrix metal is aluminum or iron.   3. The fixing roll for electrophotography according to claim 1, further comprising an elastic layer made of silicone rubber between the surface of the carbon fiber reinforced metal core roll and the release layer. The fixing device having at least one of a heating roll and a pressure roll to form a fixing nip region through which an unfixed toner image passes, wherein at least one of the heating roll and the pressure roll is of claim 1 to 3 . A fixing device comprising the fixing roll for electrophotography according to any one of the above items. In a fixing device having a pair of fixing rolls in which the heating roll and the pressure roll are pressed against each other, passing an unfixed toner image through a fixing nip region formed by a contact portion between both rolls, and fixing by heat and pressure the fixing device according to claim 4 wherein at least the heating roll of the two rolls, characterized in that it consists of the electrophotographic fixing roll according to any one of claims 1 to 3. A heating roll, a pressure belt that presses the heating roll, and a pressure roll that presses the pressure belt from behind are provided, and an unfixed toner image passes through a nip region formed by the heating roll and the pressure belt. A fixing device comprising: a fixing roll for electrophotography according to any one of claims 1 to 3 , wherein the heating roll comprises a fixing roll for electrophotography. A heating belt having at least a surface having heat resistance and releasability, a pressure member that presses the heating belt from the inside, and a pressure roll at a position facing the pressure member, the heating belt, the pressure member, and 4. The heating and pressing type fixing device that allows an unfixed toner image to pass through a nip area formed by the pressing roll and fixes the image by heat and pressure, wherein the pressing roll is any one of claims 1 to 3. A fixing device comprising the fixing roll for electrophotography described above.

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