This application is based upon and claims priority under 35 USC 119 from Japanese Patent Application Nos. 2009-204852, filed Sep. 4, 2009, and 2010-023825, filed Feb. 5, 2010.
The present invention relates to a fixing device, an image forming apparatus using the fixing device, and a toner image fixing method.
According to an aspect of the invention, a fixing device includes a laser beam irradiation unit and a conveying unit. The laser beam irradiation unit includes a plurality of laser beam sources and emits a plurality of laser beams, generated by the laser beam sources, to a surface of a recording medium. The conveying unit conveys the recording medium and/or the laser beam irradiation unit so that irradiated regions, on the recording medium, irradiated with the laser beams are moved in a given direction relative to the conveyed recording medium. When the plurality of laser beams is emitted to a toner image formed on the recording medium so as to fix the toner image to the recording medium, the plurality of laser beams satisfies conditions (A) and (B). The condition (A) is that the plurality of laser beams has substantially the same beam power and substantially the same width in the given direction in the irradiated regions. The condition (B) is that the plurality of laser beams is independently emitted to the toner image.
Exemplary embodiments of the invention will be described in detail based on the following figures, wherein:
A fixing device 1 according to this exemplary embodiment includes a plurality of laser beam irradiation units 5a and 5b. The laser beam irradiation units are disposed so as to be spaced apart from the surface of a recording medium (for example, recording sheet) 2, which is conveyed in a direction indicated by an arrow C, by a distance d. The laser beam irradiation units diffuse laser beams 4a and 4b, which are generated from the laser beam sources 3a and 3b, over a predetermined distance in a width direction crossing a conveying direction C of the recording medium 2 and emit the laser beams so that the laser beams are narrowed with a predetermined distance in the conveying direction C. The laser beam irradiation units are disposed with a gap f therebetween in the conveying direction C of the recording medium 2. When the fixing device fixes a toner image to the recording medium 2 by irradiating toner images 7 and 8, which are formed on the recording medium 2, with the laser beams 4a and 4b generated from the plurality of laser beam irradiation units 5a and 5b, the plurality of laser beam irradiation units 5a and 5b satisfies the following conditions.
(A) The plurality of laser beams 4a and 4b has the same beam power and the same width of an irradiation region in one direction.
(B) The plurality of laser beams 4a and 4b is independently emitted to the toner images 7 and 8.
(C) If the toner images 7 and 8 include a plurality of toner layers, the toner temperature of interfacial portions between the images and the surface of the recording medium 2 reaches toner fixing temperature in the irradiation of at least the final laser beam except for the irradiation of the first laser beam among the irradiation of the plurality of laser beams 4a and 4b.
Meanwhile, “independently emitted” of (B) means not that the laser beam 4b is continuously emitted after the irradiation of the laser beam 4a, but that the laser beams 4a and 4b are intermittently emitted so that non-irradiation time exists between the irradiation of the laser beams.
In this exemplary embodiment, the first laser beam irradiation unit 5a diffuses a laser beam 4a, which is generated from one laser beam source 3a, over a predetermined distance in the width direction crossing the conveying direction C of the recording medium 2 and emits the laser beam so that the laser beam is narrowed with a predetermined distance in the conveying direction C. The first laser beam irradiation unit is disposed so as to be spaced apart from the surface of the recording medium 2 by the distance d.
Further, the second laser beam irradiation unit 5b diffuses a laser beam 4b, which is generated from another laser beam source 3b, over a predetermined distance in the width direction crossing the conveying direction C of the recording medium 2 and emits the laser beam so that the laser beam is narrowed with a predetermined distance in the conveying direction C. The second laser beam irradiation unit is disposed so as to be spaced apart from the surface of the recording medium 2 by the distance d. The first and second laser beam irradiation units 5a and 5b are disposed with the gap f therebetween in the conveying direction C of the recording medium 2. That is, the second laser beam irradiation unit 5b is positioned on the rear side of the first laser beam irradiation unit 5a with the gap f between the first and second laser beam irradiation units in the conveying direction C of the recording medium 2.
Further, the laser beams 4a and 4b generated from the first and second laser beam irradiation units 5a and 5b are emitted to the toner images 7 and 8 formed on the recording medium 2, so that the toner images are fixed to the recording medium 2. In this case, in this exemplary embodiment, the plurality of laser beam irradiation units 5a and 5b satisfy the following three conditions.
Condition 1 is as follows: assuming that the beam power of the laser beam 4a emitted from the first laser beam irradiation unit 5a is denoted by W1, the width of the irradiation region by the laser beam 4a in the one direction (hereinafter referred to as the width of the irradiation region) is denoted by A1, the beam power of the laser beam 4b emitted from the second laser beam irradiation unit 5b is denoted by W2, and the width of the irradiation region of the laser beam 4b is denoted by A2, the widths A1 and A2 of the irradiation regions and the beam powers W1 and W2 of the laser beams 4a and 4b are the same as each other (W1=W2 and A1=A2). Here, the fact that the widths of the irradiation regions and the beam powers of the laser beams 4a and 4b are the same as each other means as follows: for example, when the first and second laser beam irradiation units 5a and 5b are manufactured, the first and second laser beam irradiation units are designed so that the widths of the irradiation regions and the beam powers of the laser beams 4a and 4b are the same as each other. However, even though errors are generated in the beam powers and the widths of the irradiation regions during the manufacture of the first and second laser beam irradiation units, the errors are included in the range of “the same”.
Condition 2 is as follows: the laser beams 4a and 4b emitted from the first and second laser beam irradiation units 5a and 5b are emitted to the toner images 7 and 8, which are formed on the recording medium 2 to be conveyed, several times at a predetermined time interval (for example, 5 ms). For this purpose, the recording medium 2 is conveyed in the conveying direction C at a predetermined conveying speed V (for example, 500 mm/s) by a conveying mechanism (not shown). In this case, since the widths of the irradiation regions and the beam powers of the laser beams 4a and 4b emitted from the first and second laser beam irradiation units 5a and 5b are the same as each other, the irradiation time (that is, time where the toner images formed on the recording medium are emitted with the laser beams) and the irradiation intensity of the laser beams per unit area of the recording medium 2 are the same as each other.
Condition 3 is as follows: the toner heating temperature of the interfacial portions between the surface of the recording medium 2 and the toner images 7 and 8 formed on the recording medium 2 reaches the toner fixing temperature in the irradiation of the laser beam 4b.
Here, in
Meanwhile, the toner image having high image density means a state where much toner typified by a solid image is aggregated, and the toner image having low image density means a state where one or several toner particles typified by halftone or character portions are aggregated. Further, a state where isolated toner particles generated by fogging (a phenomenon where toner is attached to non-image portions to which toner should not be attached by the development) are attached is also included in the toner image having low image density.
Further, in
In this case, as shown in
Meanwhile, in
Another embodiment of the first and second laser beam irradiation units 5a and 5b will be described below.
In
According to this exemplary embodiment, the laser beams 4a and 4b generated from the laser beam sources 3a and 3b are emitted while being diffused over a predetermined distance in the width direction r crossing the conveying direction C of the recording medium 2 by the luminous flux adjusting members 10a and 10b and being narrowed with a predetermined distance in the conveying direction C. Even in this case, two laser irradiation regions 6a and 6b, which extend linearly in the width direction r of the recording medium 2, are formed as shown in
Further, the first laser beam irradiation unit 5a may include a laser beam source 3a and luminous flux adjusting members (for example, collimator lenses) 10a. The laser beam source includes a plurality of laser beam generating elements that is lined up at the end of one substrate at a predetermined interval. The luminous flux adjusting members are provided at the ends of the emission portions for the laser beams 4a generated from the laser beam source 3a. The luminous flux adjusting members diffuse the laser beams 4a over a predetermined distance in the width direction r and narrow the laser beam with a predetermined distance in the conveying direction C. Meanwhile, like the first laser beam irradiation unit 5a, the second laser beam irradiation unit 5b also includes a laser beam source 3b and luminous flux adjusting members (for example, collimator lenses) 10b. The laser beam source includes a plurality of laser beam generating elements 9 that is lined up at the end of one substrate at a predetermined interval. The luminous flux adjusting members are provided at the ends of the emission portions for the laser beams 4b generated from the laser beam source 3b.
According to this exemplary embodiment, the laser beams 4a and 4b generated from the laser beam sources 3a and 3b, which include the plurality of laser beam generating elements lined up at the end of one substrate, are emitted while being diffused over a predetermined distance in the width direction r crossing the conveying direction C of the recording medium 2 by the luminous flux adjusting members 10a and 10b provided at the ends of the emission portions for the laser beams 4a and 4b. Further, the laser beams 4a and 4b, which linearly extend, are emitted while being narrowed with a predetermined distance in the conveying direction C. Even in this case, two laser irradiation regions 6a and 6b, which extend linearly in the width direction r of the recording medium 2, are formed as shown in
Furthermore, an image forming apparatus, to which the fixing device according to this exemplary embodiment is applied, includes an image forming device that forms a toner image on a recording medium 2, and a fixing device 1 according to each exemplary embodiment that fixes a toner image formed by the image forming device to the recording medium 2.
Exemplary embodiments of the invention will be described in detail below with reference to the accompanying drawings.
The image forming devices 21 form toner images on a recording medium 2 such as a recording sheet, for example, by an electrophotographic method. The image forming devices include image forming devices corresponding to, for example, four colors in order to form toner images having color components corresponding to a plurality of colors. Specifically, the image forming devices are formed of a black image forming device 21K, a cyan image forming device 21C, a magenta image forming device 21M, and a yellow image forming device 21Y. The respective color image forming devices 21K, 21C, 21M, and 21Y have the same structure except for color. Meanwhile, it is preferable that the toner have substantially the same absorption factor for laser beams used to fix the toner corresponding to the respective color components. In this case, the irradiation intensity and irradiation time of the laser beams, which are emitted from the plurality of laser beam irradiation units, are set to be the same in the fixing device 1, so that it is easy to fix the toner image.
The black image forming device 21K will be exemplified on behalf of the four color image forming devices. The black image forming device 21K includes a cylindrical photoreceptor that includes a photosensitive layer (not shown) on the surface thereof and is rotatable in a direction of an arrow A. A charging device 24, an exposure device 25, and a developing device 26 are provided around the photoreceptor 23. Among them, the charging device 24 charges the photosensitive layer of the photoreceptor 23 to a predetermined electric potential. The exposure device 25 includes a laser beam source (not shown), and forms an electrostatic latent image by selectively irradiating a laser beam to the photosensitive layer of the photoreceptor 23 that is charged to a predetermined electric potential by the charging device 24. The developing device 26 stores toner corresponding to the corresponding color component (here, black) as a developer, and makes the electrostatic latent image, which is formed on the photosensitive layer of the photoreceptor 23, be visible by the toner.
The transfer device 22 transfers the toner images, which are formed by the respective image forming devices 21K, 21C, 21M, and 21Y, to the recording medium 2. The transfer device includes a cylindrical or columnar transfer member that rotatably comes into contact with the photoreceptor 23 while applying pressure to the surface of the photoreceptor 23. The transfer device transfers the toner image, which is formed on the photoreceptor 23, to the recording medium 2 by applying a transfer bias between the transfer member and the photoreceptor 23.
In addition, a photoreceptor cleaner 27 is provided around the photoreceptor 23. The photoreceptor cleaner 27 removes residual toner attached to the photoreceptor 23 after the toner image is transferred to the recording medium 2 by the transfer device 22.
Meanwhile, in
Here, in the exemplary embodiment shown in
The position of the continuous recording paper is adjusted by a plurality of position adjusting rollers 32, 33, 34, and 35 provided on a path where the continuous recording paper passes so that the position of the continuous recording paper is not deviated during the conveyance of the continuous recording paper. The adjustment of the position of the continuous recording paper is a process that is to be performed before the image is transferred to the recording medium 2. Further, a tension applying roller 36 provided at the end is supported by a pushing member (not shown) so that the tension applying roller is movable in a direction of an arrow B and tension reaches a predetermined intensity during the conveyance of the continuous recording paper. While the continuous recording paper is wound up, the position of the continuous recording paper is adjusted by the tension applying roller 36 so that the continuous recording paper is not broken.
The detailed structure of the fixing device 1 for fixing the toner image, which is transferred by the transfer device shown in
In
The laser beam irradiation units 5a, 5b, and 5c are disposed so as to be spaced apart from the surface of the recording medium 2, which is conveyed in a direction of an arrow C, by a distance d (see
Meanwhile, the recording medium 2 is conveyed in a direction of an arrow C by a conveying mechanism, which includes two conveying rollers (not shown) and a conveying belt stretched between the two conveying rollers, while being placed on the conveying belt.
Further, three laser beam irradiation units 5a, 5b, and 5c, which are formed by laminating three substrates 11 with a predetermined gap therebetween, have been shown in
The operation of the fixing device 1 having the above-mentioned structure will be described below. An exemplary embodiment where the fixing device 1 shown in
In
Further, since the recording medium 2 is conveyed at a predetermined conveying speed v (for example, 500 mm/sec) by a conveying mechanism (not shown), a laser beam is emitted to the toner images 7 and 8, which are formed on the recording medium 2, two times at a predetermined time interval (for example, 5 msec) while two laser beams 4a and 4b are emitted from the first and second laser beam irradiation units 5a and 5b (Condition 2). That is, in
Further, due to the above-mentioned irradiation of the laser beams 4a and 4b, the toner heating temperature of the interfacial portions between the surface of the recording medium 2 and the toner images 7 and 8 formed on the recording medium 2 reaches toner fixing temperature in the irradiation of at least the final (for example, second in the case of two light sources) laser beam except for the irradiation of one laser beam among the irradiation of the plurality of laser beams 4a and 4b (Condition 3). Accordingly, not only the toner image 7 having high image density but also the toner image 8 having low image density is fixed to the recording medium 2.
Here, graphs shown in
In
Then, while a laser beam is not emitted for 2 ms, the toner temperature of the surface layer portion of the toner image 7 is also lowered below the toner fixing temperature together with the toner temperature of the interfacial portion between the recording medium 2 and the toner image (solid change curve 12 and dashed change curve 13). Accordingly, in the irradiation of the first laser beam 4a, the toner image 7 is not fixed as a whole.
After that, since the second laser beam 4b is emitted by the second laser beam irradiation unit 5b, the surface layer portion is heated from a state where the surface layer portion is cooled after the irradiation of the first laser beam 4a. Accordingly, the toner temperature of the surface layer portion of the toner image 7 exceeds the toner fixing temperature again (solid change curve 12), and the toner temperature of the interfacial portion between the recording medium 2 and the toner image also exceeds the toner fixing temperature (dashed change curve 13). That is, the entire portion of the toner image 7 between the surface layer portion and the interfacial portion, which is formed between the recording medium 2 and the toner image, reaches the toner fixing temperature due to the irradiation of the second laser beam 4b. Accordingly, the toner image 7 is fixed as a whole by the irradiation of the second (final) laser beam 4b through the irradiation of the first and second laser beams 4a and 4b.
Each of
Further,
Furthermore,
In
Then, while a laser beam is not emitted for 2 ms, the toner temperature of the surface layer portion of the toner image 8 is also lowered to the toner temperature, which is obtained before the irradiation of the first laser beam 4a, together with the toner temperature of the interfacial portion between the recording medium 2 and the toner image (solid change curve 15 and dashed change curve 16). The reason for this is that the amount of radiated heat is increased since the contact area between each toner particle and air is large in the toner image, which has low image density and has about one, two, or three toner particles.
After that, since the second laser beam 4b is emitted by the second laser beam irradiation unit 5b, the toner temperature of the surface layer portion of the toner image 8 exceeds the toner fixing temperature (solid change curve 15) and the toner temperature of the interfacial portion between the recording medium 2 and the toner image also exceeds the toner fixing temperature (dashed change curve 16), as in the case of the irradiation of the first laser beam 4a. Accordingly, the toner image 8 is fixed even by the irradiation of the second laser beam 4b.
Meanwhile, in the above description of the operation, there has been described an exemplary embodiment where the fixing device 1 shown in
In this case, depending on the irradiation time and beam power of a laser beam, for example, due to the irradiation of the second laser beam, the entire portion of the toner image 7 between the surface layer portion and the interfacial portion, which is formed between the recording medium 2 and the toner image, may reach the toner fixing temperature and the toner image 7 may be fixed as a whole. That is, due to the irradiation of at least the final (third) laser beam except for the irradiation of the first laser beam, the entire portion of the toner image 7 between the surface layer portion and the interfacial portion, which is formed between the recording medium 2 and the toner image, reaches the toner fixing temperature and the toner image 7 is fixed as a whole.
In this case, due to the irradiation of at least one laser beam of the first to third laser beams, the toner temperature of the surface layer portion of the toner image 8 exceeds the toner fixing temperature and the toner temperature of the interfacial portion between the image and the surface of the recording medium 2 also exceeds the toner fixing temperature in a graph that shows a relationship between the change in toner temperature and irradiation time shown in
In this case, depending on the irradiation time and beam power of a laser beam, for example, due to the irradiation of the second or third laser beam, the entire portion of the toner image 8 between the surface layer portion and the interfacial portion, which is formed between the recording medium 2 and the toner image, may reach the toner fixing temperature and the toner image 8 may be fixed as a whole. That is, due to the irradiation of at least the final (third) laser beam, the entire portion of the toner image 8 between the surface layer portion and the interfacial portion, which is formed between the recording medium 2 and the toner image, reaches the toner fixing temperature and the toner image 8 is fixed as a whole.
Meanwhile, in
The invention will be described in more detail below with reference to examples that make a prototype of the fixing device and perform a fixing experiment for fixing a toner image to a recording medium.
First, DocuColor 1256GA (electrophotographic apparatus) manufactured by Fuji Xerox Co., Ltd. was used as an image forming apparatus. In the image forming apparatus, a recording medium, to which unfixed toner images were transferred, was formed by using the following toner for laser fixing as an image forming material.
As the toner for laser fixing, there was used an image forming material obtained by adding 0.5% of an infrared absorbing material, which absorbs a beam of which the wavelength was similar to the wavelength of a laser beam, to color toner, such as yellow, magenta, and cyan toner so that the image forming material absorbed the laser beam. For example, there was an image forming material containing a perimidine squarylium dye. The infrared absorbing material has low absorbancy in a visible light wavelength region where a wavelength is equal to or larger than 400 nm and smaller than 750 nm, and has high absorbancy in a near-infrared light wavelength region where a wavelength is equal to or larger than 750 nm and smaller than 1000 nm. In this example, a perimidine squarylium dye represented by the following structural formula (I) was used as the infrared absorbing material. It may be possible to obtain this material by a method disclosed in Japanese Patent Application No. 2008-055291.
Further, as laser beam irradiation devices of a fixing device 1, there were used two laser beam irradiation devices (which correspond to reference numerals 5a and 5b shown in
In this state, the laser beam irradiation units 5a and 5b were disposed above a moving stage that conveys the recording medium 2 so that the laser irradiation regions 6a and 6b shown in
In Example 2, the same image forming apparatus and toner for laser fixing as those of Example 1 were used and the following fixing device 1 was used.
As laser beam irradiation devices of the fixing device 1, there were used stacked laser beam irradiation units where two semiconductor laser arrays (which correspond to reference numerals 5a and 5b shown in
In this state, the laser beam irradiation units 5a and 5b were disposed above a moving stage for conveying the recording medium 2 so that the laser irradiation regions 6a and 6b shown in
In Comparative example 1, the same image forming apparatus and toner for laser fixing as those of Example 1 were used and the following fixing device 1 was used.
As the fixing device, there was used a fixing device including one laser beam irradiation unit (which corresponds to reference numeral 5a shown in
In Comparative example 2, the same image forming apparatus and toner for laser fixing as those of Example 1 were used and the following fixing device 1 were used.
As the fixing device, there was used a fixing device including one laser beam irradiation unit (which corresponds to reference numeral 5a shown in
A table of
First, as for the image regions of the recording medium 2, a recording sheet was folded in half at a certain position of the image region so that images were positioned inward. Then, the recording sheet was turned back, and the recording sheet was rubbed with a cotton cloth. Further, whether images (toner images) of a folded portion were peeled and image defects were generated were visually observed and evaluated on the basis of the following criteria.
A: the images (toner image) are not peeled and image defects are also not generated at the folded portion.
B: the peeling of the images (toner images) appears at the folded portion along a folding line.
C: the peeling of the images (toner images) is generated even near the folding line or noticeable image defects are generated at the folded portion.
After that, as for the non-image regions (low image density portions) of the recording medium 2, an image surface having an image density of 10% was rubbed with a cotton cloth with a predetermined pressure, and the comparison of the change in the image density before and after the rubbing were visually observed and evaluated on the basis of the following criteria.
A: the image density is not changed before and after the rubbing.
B: the change of the image density appears before and after the rubbing.
C: the image density after the rubbing significantly deteriorates in comparison with the image density before the rubbing.
The results of the evaluation of the fixing property, which are based on the above-mentioned evaluation method and evaluation criteria, were shown in the table of
Example 1 had a good fixing property without the peeling of the toner images in not only the image regions but also the non-image regions.
Example 2 had a good fixing property without the peeling of the toner images in not only the image regions but also the non-image regions.
Comparative example 1 had no peeling of the toner images in not only the image regions but also the non-image regions, but had cavities at the inner layer portion in the image regions, so that image defects were generated. Accordingly, Comparative example 1 had a poor fixing property in the image regions.
Comparative example 2 had no peeling of the toner images in the image regions, but had the peeling of the toner images in the non-image regions. Accordingly, Comparative example 2 had a poor fixing property in the non-image regions.
The foregoing description of the exemplary embodiment of the present invention has been provided for the purpose 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 various will be apparent to practitioners skilled in the art. The exemplary embodiments were chosen and described in order to best explain the principles of the invention and its practical application, thereby enabling other 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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2009-204852 | Sep 2009 | JP | national |
2010-023825 | Feb 2010 | JP | national |