This patent specification is based on two Japanese patent applications, No. 2006-183189 filed on Jul. 3, 2006 in the Japan Patent Office and No. 2007-068563 filed on Mar. 16, 2007 in the Japan Patent Office, the entire contents of which are incorporated by reference herein.
1. Field of the Invention
The present invention relates to an image forming apparatus, such as a copy machine, a printer, a facsimile machine, and a multi-function machine capable of copying, printing, and faxing, and more particularly to an image fixing device which uses a carbon lamp.
2. Description of the Related Art
An image fixing device is disclosed in Laid-open Japanese Patent Application No. 2003-215964 as Patent Reference 1. This image fixing device is improved to suppress an inrush current at an initial energization of a heater used for a fixing device for an image forming apparatus. A thermal fixing device of paper having an unfixed image may be implemented using a halogen lamp and a carbon lamp which heat a fixing roller. The carbon lamp radiates more far infrared radiation larger than the halogen lamp. The halogen lamp is usually inside the core of the fixing roller, and the carbon lamp is arranged mechanically parallel to and near the halogen lamp. The carbon lamp is electrically connected to the halogen lamp in series or parallel. The halogen lamp, which is used as a conventional heat source, lets an inrush current occur when the halogen lamp is in a cool state because a resistance of the halogen lamp is low. The inrush current causes a voltage drop and a lighting flicker for the halogen lamp. To prevent the voltage drop and the lighting flicker, the electronic power source of the halogen lamp needs to have a large source capacity or a current control system.
Patent Reference 1 discloses that the image fixing device solves the voltage drop and a lighting flicker. The image fixing device has the halogen lamp as a first heating member and the carbon lamp as a second heating member for heating the fixing roller. The carbon lamp is one part of a protecting circuit to prevent the inrush current from occurring. However it is not cost effective to arrange both the halogen lamp and the carbon lamp in the fixing roller. Moreover to arrange both the halogen lamp and the carbon lamp in the fixing roller makes it difficult to downsize the heating member. A large heating member makes a heat capacity large and the large heat capacity of the fixing roller makes the time for heating the fixing roller large.
The invention presented in this application prevents the inrush current from occurring with a simple structure. Further, the invention allows the electric power source capacity to be smaller as the power source does not need to supply the inrush current.
According to an aspect of the invention, an image fixing device for use in an image forming apparatus includes a fixing member which fixes a toner image on a recording medium at a nip area, a pressurizing member which pressures the recording medium toward the fixing member at the nip area, a carbon lamp which emits infrared rays, and a reflecting member which reflects the infrared rays to the nip area. The carbon lamp and the reflecting member suppress an inrush current at an initial energization, and allow the electric source capacity to be small. Moreover, the carbon lamp and the reflecting member make the time of heating up the fixing member short and effectively melt and press toner at the nip area. The reflecting member reflects the infrared rays to a most upstream portion of the nip area in the conveying direction of the recording medium. This reflecting member heats toner at the beginning of proceeding the nip area and prevents ineffectual loss of heat. Moreover, the thermistor which is a detecting member for detecting temperature of the fixing member and is opposed to the inner side of fixing member prevents the accuracy of detecting temperature from dropping.
The fixing member includes a plurality of materials which have different heat absorptivities. The plurality of materials allows better absorption of the heat energy corresponding to the wavelength range of the infrared rays emitted by the carbon lamp. Moreover, the fixing member is made with at least a first layer which contacts the recording medium, a second layer which conveys heat to the first layer, and a third layer which includes a surface facing the carbon lamp. The first, second, and third layers have different heat absorptivities, and convey heat from the third layer, whose heat absorptivity is the highest in the layers of the fixing member, to the first layer which is next to the recording medium. The third layer absorbs the far infrared rays corresponding to the infrared rays given off from the carbon lamp whose wavelength range is mainly from 1 to 10 μm.
The material of the third layer is made with heat resistant resin, and prevents the third layer from a deformation or a chemical change caused by the heat of the carbon lamp. The thickness of the third layer is 0.5 mm or less and makes the heat capacity of the fixing member small. The small heat capacity of the fixing member reduces the heat up time at the nip area of the fixing member.
The carbon lamp includes the evaporated reflecting member on the surface of the lamp. The evaporated reflecting member does not need an attachment structure of the reflecting member, and downsizes the image fixing device. A small image fixing device has a small heat capacity and the small heat capacity of the small image fixing device also reduces the heat up time at the nip area of the fixing member. According to one embodiment, the image fixing device includes a plurality of carbon lamps arranged in the width direction of the fixing member which give off a limited infrared ray selectively corresponding to the different widths of the recording mediums. The plurality of carbon lamps prevent the excess heating up at both ends of the fixing member in the width direction where the recording medium does not contact but the fixing member directly contacts with the pressurizing member. The heat damage at both ends is decreased and the heating efficiency is increased.
In describing example embodiments shown in the drawings, specific terminology is employed for the sake of clarity. However, the disclosure of this present invention is not intended to be limited to the specific terminology so selected and it is to be understood that each specific element includes all technical equivalents that operate in a similar manner. In the following, the same reference mark is given to the same device in the drawings, and explanations thereof are not repeated.
The intermediate transferring device 8 has an intermediate transferring belt which is in contact with the four drums 1, and a plurality of rollers which are arranged inside of the intermediate transferring belt and help the intermediate transferring belt to rotate. The secondary transferring roller is in contact with the intermediate transferring belt at the downstream side of the photoconductive drums 1 in the conveying direction of the color toner images. Each color toner image formed on the photoconductive drum 1 by the developing device 4 is transferred to the intermediate transferring device 8 in series. The color toner images are superimposed and become a full color toner image on the intermediate transferring belt. Then, the full color toner image is transferred to a recording medium P, which is conveyed to the contact position between the intermediate transferring belt and the secondary transferring roller 10 by the secondary transferring roller 10. Then, the recording medium P, on which the toner image is transferred, is conveyed to the image fixing device 7. There, the toner image is fixed by heat and pressure provided by the fixing device 7. The recording medium P to which the toner image is fixed is subsequently discharged from the fixing device 7 to the delivery tray (not shown).
The carbon lamp 13 has properties described with respect to
The second property is a tolerability of the carbon lamp 11 against an inrush current. A halogen lamp, which is adopted in the conventional fixing device, includes a tungsten wire. The tungsten wire heats well but the resistance of the tungsten wire is so small in a room temperature that the inrush current, which is from several to dozens of times the current rating, happens sometimes at an initial energization. To prevent the inrush current, the conventional art offers an addition of a protection circuit such as an inrush current suppressors to a circuit for the halogen lamp. To the contrary, the resistance of the carbon plate 13b of the carbon lamp 13 is much larger than the resistance of the tungsten wire. There is some data of the volume resistivity of the same form test pieces in 20° C. circumstance. The volume resistivity of the tungsten piece is 5.6×10−8 Ω·m and the volume resistivity of the carbon piece is 3352.8×10−8 Ω·m, i.e., carbon resistance is about six hundred times larger than tungsten resistance in 20° C. As a result, the carbon lamp 13 prevents the inrush current from occurring at the initial energization in room temperature.
A third property is a rapid temperature rise of the carbon lamp 13. The carbon lamp 13 heats up to its maximum temperature in several seconds after the initial energization. As explained above, the resistance of the carbon plate 13b is so large that a heat amount, which happens at the same time of energization, is also large. Additionally, molding the shape of the carbon plate 13b is easy so it is not difficult to design the cross section of the carbon plate 13b, which makes a large current get trough the cross section even when a large voltage is applied to the carbon plate 13b. As a result, the carbon lamp 13 can heat up rapidly. The amount of passing current in the carbon plate 13b is so large and the resistance of the plate 13b is so large that the heat amount produced from the carbon lamp 13 per unit time is also large. The carbon lamp 13 is an effective heating device and has the three properties explained above. However, to broaden simply the cross section of the carbon plate 13b makes the heat produced by the carbon plate 13b sprawl. As a result, it is difficult for the carbon lamp 13 to heat up the nip area intensively. Therefore in the first embodiment, the carbon plate 13b includes a thin rectangle, and one of the broader surfaces in the rectangle is arranged opposed to the nip area. The design of the carbon plate 14b helps almost half of the light amount produced by the carbon plate 13b to arrive at the nip area directly, in theory. Furthermore the first embodiment adopts the reflecting member or reflector 14. The reflecting member includes a cylindrical shape, part of which is opened towards the nip area and reflects the infrared rays given off from the carbon lamp to the nip area and the portion around the nip area. The cylindrical shape is made with stainless, for example, and the inner surface of the cylindrical shape is mirrored. Alternatively, the cylindrical shape may be made with a base cylindrical portion and a lamination layer made of aluminum foil and glass is formed on the inner surface of the base cylindrical portion. The light given off from the carbon lamp 13, which does not directly arrive at the nip area, is reflected by the reflecting member 14 to the nip area via an opening of the cylindrical shape of the reflecting member 14.
The improved embodiment based on the embodiment 1 is shown in
The third embodiment of the present invention will now be described.
On the condition that the upper graph's wavelength distribution of the light which is given off by the carbon lamp corresponds to the far infrared ray's range from 2.5 to 8 μm, either lower graph's wavelength distribution of heat absorptivity which is the fixing member's material A or B shown in
On the condition that each material has a limited wavelength distribution range of heat absorption, it is preferable for the fixing member to be made with a plurality of the materials which have different heat absorptivities from each other. The fixing member broadens the wavelength range in which the fixing member can absorb the heat energy. As a result, the fixing member can heat up effectively.
The carbon lamp 13 includes a cylindrical glass housing 13a and a carbon plate 13b inside the housing. A cross section of the carbon plate 13b is a thin rectangle because the thin plate has two broader surfaces and the broad surfaces direct the irradiation of the infrared ray in a certain line opposed to the broad surfaces. A lamination layer 141, which is an evaporated reflecting member, is evaporated on the glass 13a of the carbon lamp 13.
Preferable materials for the lamination layer 141, which include high heat reflectivities against the carbon lamp's infrared wavelength from 1 to 10 μm, include e.g. aluminum, gold, silver, copper and so on. It is preferable to evaporate the lamination layer 141 directly on the glass 13a because the evaporated layer 141 gives some directivities to the infrared ray of the carbon lamp 13. However, this is not required. It is also preferable to make the lamination layer 141 on the glass 13a by sputtering. The surface layer 22 is made with a heat resistant material which is elastic and releasable for the recording medium, e.g. silicone, teflon coat and so on. The middle layer 21 supports the inner layer 20 and the surface layer 22, and is made with a high heat conductive material which is rigid, e.g. iron, copper, copper alloy, and aluminum. The inner layer 20 is made with a material which absorbs the infrared ray effectively and whose surface does not reflect the infrared ray. It is preferable for the inner layer 20 to be made with a material which has a heat absorptivity for a wavelength range from 1.5 to 8 μm. The infrared rays are distinguished into two types; near infrared rays less than 2.5 μm and far infrared rays from 2.5 to 1000 μm.
Infrared rays are electromagnetic rays, and electromagnetic rays vibrate molecules in the material of the fixing member. The heat absorptivity from the infrared rays is determined by the molecular binding. Materials which absorb the infrared ray effectively and are preferable materials for the inner layer 20 include natural resin, synthetic resin, rubber, coating medium, wood, fabric, glass, natural ceramics, and artificial ceramics.
An organic matter's wavelength of heat absorptivity corresponds to the wavelength of the infrared ray, and organic matter is preferable for the material of the inner layer 20. Moreover, ceramics which contains alumina or zirconia are also preferable materials for the inner layer 20.
There are some methods to manufacture the inner layer of ceramics, e.g. coating ceramics on the middle layer 21, presintering ceramics, and thermal spraying of ceramics. Thermal spraying is preferable to other methods because thermal spraying allows the free selection of material and does not restrict the shape of middle layer 21. However, the invention is not limited to thermal spraying.
Moreover, an oxidized metal is also a preferable material for the inner layer 20 because the oxidized metal absorbs infrared rays effectively. Moreover black chrome plating is also a preferable method for making the inner layer 20. The wavelength of the near infrared ray is shorter than the wavelength of the far infrared ray and overlaps a range of optical wavelengths. A heat absorptivity of the optical wavelength depends on the color of the surface to which the light is irradiated. Accordingly dark color or black is preferable for the surface color in order to absorb the heat energy of near infrared rays, and this is the reason why black chrome plating is also preferable for the inner layer 20. A method of mixing the inner layer 20 materials with carbon or an oxidized metal is also preferable in order to make the inner layer 20 black. Carbon is a preferable material to absorb the heat energy of the infrared rays.
Moreover the heat absorptivity from infrared rays depends on differences of surface properties of the inner layer 21, even if the inner layer is made with the same material and color. The heat absorptivity is expressed by the following formula:
heat absorptivity+heat reflectivity+heat transmissivity=1
The more specular the inner layer surface becomes, the larger the heat reflectivity of the inner layer is and the smaller the heat absorptivity of the inner layer is. In contrast, it is preferable to make the inner layer 20 surface rough in order to make the heat absorptivity large, because a rough surface maintains a small heat reflectivity. The surface of the inner layer 20 may be made rough by sandblasting, grinding, and/or thermal spraying a resin or ceramic. A preferable roughness is equal or more than Ra 1 μm. In order to convey heat from the inner layer 20 to the surface layer 22, it is preferable to make all three layers as thin as possible. For example, a preferable thickness of the inner layer 20 is equal to or less than 0.5 mm. A 200 μm thickness of the layer 20 is enough to absorb the heat energy from the infrared rays. It is also preferable to nickelize the middle layer 21 with a nickel layer of the thickness from 20 to 200 μm. A preferable thickness of the surface layer 22 is from 20 to 300 μm because such thickness prevents uneven luster gloss or creases on the recording medium P from occurring.
Various polymers and molecular structures or compounds may be utilized with the invention.
Polyimides which include [—NH] radicals and [C—O] radicals in their molecular feature or structure effectively absorb infrared wavelengths from 2.8 to 3.1 μm and from 9.2 to 9.5 μm. Polyamideimides include [—NH] radicals in their molecular feature or structure and effectively absorb infrared wavelengths from 2.8 to 3.1 μm. Silicone includes a [—OH] radical and a [—CH3] radical in its molecular feature or structure and effectively absorbs infrared wavelengths from 2.9 to 3.2 μm and from 6.6 to 6.9 μm. Phenols include [—OH] radicals and [—CH2] radicals in their molecular feature or structure and effectively absorb infrared wavelengths from 2.9 to 3.2 μm and from 6.6 to 6.9 μm.
Ketone polyether includes a [>C=O] radical in its molecular feature or structure and effectively absorbs infrared wavelengths from 5.5 to 6.1 μm. Polyimide, polyamide, polyamideimide, silicone, phenol, and ketone polyether are preferable materials for the inner layer 20 because they have some preferable radicals for infrared absorption in their molecular features and high heat resistances. As well as the first embodiment, the embodiments described in
The present invention may be implemented using a controller, processor, or microprocessor. The coding or programming for these devices can readily be prepared by skilled programmers based on the teachings of the present disclosure. The invention may also be implemented by the preparation of application specific integrated circuits or by connecting an appropriate network of conventional component circuits, as will be readily apparent to those skilled in the art.
The present invention also includes a computer program product which is a storage medium including instructions which can be used to program a computer to perform a process of the invention. The storage medium can include, but is not limited to, any type of disk including floppy disks, optical disks, CD-ROMs, and magneto-optical disks, ROMs, RAMs, EPROMs, EEPROMs, flash memory, magnetic or optical cards, or any type of media suitable for storing electronic constructions. The invention also includes a memory such as any of the described memories herein which store data structure corresponding to the information described herein. Moreover, the invention also includes signals such as carrier waves which transmit the data structures and also the software coding corresponding to the computer program product of the invention.
Obviously, numerous modifications and variations of the present invention are possible in light of the above teachings. It is therefore to be understood that within the scope of the appended claims, the invention may be practiced otherwise than as specifically described herein.
Number | Date | Country | Kind |
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2006-183189 | Jul 2006 | JP | national |
2007-068563 | Mar 2007 | JP | national |