JP2005173339A - Flash fixing device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To fix a toner image transferred on a recording medium, without making voids, etc generated. <P>SOLUTION: This flash fixing device which fixes the toner image transferred on the recording medium is provided with flash fixing units 46, 47 (refer to (A)), to which four flash lamps 48 are provided for each. In the fixing unit 47 arranged on the downstream side of a conveyance direction of the recording medium, light-emitting intensity α of flash light is set so as to be sufficient for toner image fixation and in the fixing unit 46 arranged on the upstream side, light-emitting intensity β of the flash light is set to about 70 to 80% of α (refer to (B)). The toner image on the recording medium is first gradually melted, without occurrence of the void, etc. by energy β supplied by the flash light from the fixing unit 46 and fixed to the recording medium without generation of the void, etc. by energy α supplied by the flash light from the fixing unit 47, after toner composition to be a cause of the void, etc. has been removed. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a flash fixing device, and more particularly to a flash fixing device that fixes a toner image transferred onto a recording medium by irradiating flash light emitted from a flash lamp.

  An image forming apparatus that forms an image using an electrophotographic method transfers thermal energy to a recording medium (powder toner on the recording medium) onto which the toner image has been transferred after transferring the toner image formed with powder toner onto the recording medium. In addition, the toner image is fixed on the recording medium by melting the powder toner. A heat roller is often used to supply heat energy for fixing a toner image, but a high-capacity image forming apparatus capable of forming a large amount of images at a high speed (for example, an area of about 500 sheets per second in terms of A4) In an image forming apparatus that can form an image on a recording medium, the energy for fixing the toner image by melting the powder toner by intermittently lighting the flash lamp and irradiating the flash light emitted from the flash lamp when the lamp is turned on. A flash fixing method is used to supply the toner.

For example, in Patent Document 1, in a flash fixing device having a plurality of flash lamps, the number of capacitors for charging / discharging is smaller than the number of flash lamps, and a trigger voltage is selectively supplied only to the flash lamps to emit light. Thus, there is disclosed a configuration that realizes cost reduction and downsizing by emitting light. Since the flash fixing method can supply high energy without contacting the recording medium, it is suitable for high-speed image formation without affecting the conveyance of the recording medium.
JP 2000-47517 A

  By the way, high-capacity image forming apparatuses are mainly used for printing forms, and most of them are monochrome. However, even for printing forms, for example, corporate logos to be added to forms as headers or footers in color. There is a gradual need for colorization of high-capacity image forming apparatuses such as printing. Formation of a color image in the electrophotographic method can be realized by superimposing toner images of C, M, Y (and K) colors, and the amount of toner transferred to a recording medium (toner to be fixed) The amount of toner) increases, and it becomes necessary to supply more energy for fixing the toner image.

  In the flash fixing method, increasing the supply energy decreases the conveyance speed of the recording medium (for example, if the conveyance speed is halved, the supply energy is doubled) or shortens the light emission period of the flash lamp. (For example, if the light emission period is halved (the light emission frequency is doubled), the supply energy is doubled). However, lowering the conveyance speed of the recording medium is not desirable because it leads to a reduction in the processing capability of the image forming apparatus, shortening the light emission cycle of the flash lamp, shortening the life of the flash lamp, and increasing the lamp temperature. There is a problem that it gets bigger.

  Further, if the number of flash lamps is increased, the supply energy can be increased without reducing the conveying speed or shortening the light emission cycle. However, if a large amount of energy is supplied to the toner image at once, the toner composition (for example, Sublimation (explosion) of water contained in the toner causes image quality degradation such as missing dots (white dots) called voids in the image formed on the recording medium (see FIG. 7 as an example). reference). Further, the amount of dust increases with the sublimation of the toner composition, and there is a problem that the life of the smoke removal filter attached to the image forming apparatus is shortened.

  The present invention has been made in consideration of the above facts, and an object thereof is to obtain a flash fixing device capable of fixing a toner image transferred to a recording medium without causing voids or the like.

  In order to achieve the above object, a flash fixing device according to a first aspect of the present invention includes first and second flash lamps that emit flash light for fixing a toner image transferred onto a recording medium, and a fixing target. The second flash emitted from the second flash lamp after irradiating the first flash light emitted from the first flash lamp to the respective parts on the recording medium onto which the toner image is transferred The first and second flash light is irradiated and the energy supplied to the toner image by the first flash light is smaller than the energy supplied to the toner image by the second flash light. Driving means for causing the flash lamp to emit light.

  A flash fixing device according to a first aspect of the present invention includes a first flash lamp and a second flash lamp. Each of the first and second flash lamps may be composed of a single flash lamp, or may be composed of a plurality of flash lamps. The driving unit emits the first flash light emitted from the first flash lamp to each part on the recording medium onto which the toner image to be fixed is transferred, and then emits the second flash lamp. The first and second flash lights are irradiated and the energy supplied to the toner image by the first flash light is smaller than the energy supplied to the toner image by the second flash light. Turn on the flash lamp.

  As described above, in the first aspect of the invention, the energy supplied to the toner image by the first flash light is made smaller than the energy supplied to the toner image by the second flash light. Each of the toners forming the toner image is first melted by increasing the temperature with a relatively small inclination by the relatively small energy supplied by the irradiation of the first flash light, The toner component that causes the above is removed by gradually vaporizing during this period. In addition, each of the toners is melted at a further increased temperature due to the relatively large energy supplied by irradiation with the second flash light, but at this time, the toner component that causes voids is removed. Therefore, the toner image is fixed on the recording medium without any voids. Therefore, according to the first aspect of the present invention, the toner image transferred to the recording medium can be fixed without causing voids or the like.

  In the first aspect of the present invention, the energy supplied to the toner image by the first flash light can be set to such a magnitude that the melting of the toner is started, for example, as described in the second aspect. . As a result, the energy supplied by the irradiation of the first flash light can surely remove the toner composition that causes the void and the like without causing the void or the like.

  Further, in the first aspect of the present invention, the drive means is configured so that the energy supplied to the toner image by the first flash light is large enough to fix the toner image. It is preferable to make the first flash lamp emit light so that it is 70 to 80% of α. As a result, as apparent from the results of experiments conducted by the inventors of the present application (described later), it is possible to fix the toner image while reliably suppressing the generation of voids.

  In the first aspect of the invention, for example, the energy supplied to the toner image by the first flash light is made smaller than the energy supplied to the toner image by the second flash light. As described above, the number of flash lamps that emit light as the first flash lamp is different from the number of flash lamps that emit light as the second flash lamp (the number of flash lamps that emit light as the first flash lamp is the second number). Less than the number of flash lamps that emit light).

  Further, in the first aspect of the invention, the energy supplied to the toner image by the first flash light is made smaller than the energy supplied to the toner image by the second flash light. As described above, the voltage supplied to the flash lamp (the supply energy increases as this voltage increases), the capacitance of the capacitor connected in parallel to the flash lamp (the supply energy as this capacitance increases) And at least one of the light emission period (the supply energy increases as the light emission period becomes shorter) is made different between the first flash lamp and the second flash lamp.

  In the first aspect of the invention, the toner image to be fixed may be a monochrome (single color) toner image. However, in the first aspect of the invention, the first and second flash lights are used as the toner image. By sequentially irradiating, relatively large energy can be supplied without generating voids or the like. For example, as a toner image to be fixed, a plurality of color toner images are superimposed. Colored toner images are preferred.

  As described above, according to the present invention, after the first flash light from the first flash lamp is irradiated to each part on the recording medium to which the toner image to be fixed is transferred, the second flash lamp is used. And the energy supplied to the toner image by the first flash light is made smaller than the energy supplied to the toner image by the second flash light. It has an excellent effect that the transferred toner image can be fixed without causing voids or the like.

  Hereinafter, an example of an embodiment of the present invention will be described in detail with reference to the drawings. FIG. 1 shows a color image forming apparatus 10 according to this embodiment. The color image forming apparatus 10 is an apparatus that forms a color image on a recording medium 12 made of continuous paper. The recording medium 12 inserted into the body of the color image forming apparatus 10 is wound around winding rollers 14 and 16. Then, it is transported at a constant speed along a transport path formed so as to cross the body. Image forming units 18A, 18B, 18C, and 18D that form toner images of C (cyan), M (magenta), Y (yellow), and K (black) colors are provided below the conveyance path of the recording medium 12. It arrange | positions along the conveyance path at substantially equal intervals.

  The image forming units 18 </ b> A to 18 </ b> D have the same configuration except for the color of the toner image to be formed, and include a photoconductive drum 20 arranged so that the axis is orthogonal to the conveyance direction of the recording medium 12. The charger 22 for charging the photosensitive drum 20, the light exposure device 24 for irradiating the charged photosensitive drum 20 with LED light to form an electrostatic latent image, and the static on the photosensitive drum 20. A developer 26 for forming a toner image of a predetermined color on the photosensitive drum 20 by supplying toner of a predetermined color to the electrostatic latent image forming portion to develop the electrostatic latent image, and a conveyance path of the recording medium 12 sandwiched therebetween. A transfer device 28 disposed opposite to the photosensitive drum 20, a static eliminator 30 for neutralizing the photosensitive drum 20, a cleaner blade 32 and a cleaner brush 34 for removing residual toner on the photosensitive drum 20 are arranged. It is.

  The image forming units 18 </ b> A to 18 </ b> D form toner images of different colors on the peripheral surface of the photosensitive drum 20 by the charging device 22, the light exposure device 24, and the developing device 26, and then transfer the formed toner images by the transfer device 28. Transfer to the recording medium 12. A series of processes of charging, exposure (electrostatic latent image formation), development (toner image formation), and transfer in each of the image forming units 18A to 18D is performed by the toner image formed by each of the image forming units 18A to 18D on the recording medium 12. The execution timing is controlled so as to overlap each other. As a result, a full-color toner image is formed on the recording medium 12.

  In addition, the conveyance direction of the recording medium 12 is reversed by the winding rollers 38 and 40 on the downstream side of the arrangement positions of the image forming units 18A to 18D, and the space between the winding roller 40 and the subsequent winding roller 42 is reversed. In this section, the recording medium 12 is conveyed obliquely downward at an angle close to horizontal. A first flash fixing unit 46 and a second flash fixing unit 47 are sequentially arranged above the conveyance path in the section between the winding rollers 40 and 42.

  The flash fixing units 46 and 47 have the same configuration, and as shown in FIG. 2A, flash light for supplying energy for fixing the toner image transferred to the recording medium 12 (melting the toner) is used. Four flash lamps 48A to 48D for emitting light are provided. Each flash lamp 48 is oriented so that its longitudinal direction is along the width direction of the recording medium 12 (direction perpendicular to the conveyance direction of the recording medium 12), and is arranged at regular intervals along the conveyance direction of the recording medium 12. . Further, the back side of the flash lamp 48 as viewed from the conveyance path side of the recording medium 12 surrounds the back side of the four flash lamps 48 and has an opening formed on the front side (conveyance path side). A reflecting plate 50 is provided that reflects the flash light emitted from the lamp 48 to the back side toward the transport path.

  The reflector 50 has a shape or the like so that when the flash lamps 48 </ b> A to 48 </ b> D emit light, the flash light applied to the recording medium 12 has a substantially uniform light amount (= energy) over substantially the entire irradiation range. It has been adjusted. A cover glass 52 is disposed on the front side (conveyance path side) of the flash lamp 48. The cover glass 52 is provided so as to close the opening of the reflecting plate 50, and the cover glass 52 prevents dust and the like from entering the flash fixing unit 46.

  The individual flash lamps 48 of the flash fixing units 46 and 47 are connected at both ends to a power supply circuit 58 as shown in FIG. That is, one end of the flash lamp 48 is connected to the power supply terminal 64 </ b> B, and the other end of the lamp 48 is connected to one end of the choke coil 60. The other end of the choke coil 60 is connected to the power supply terminal 64A and one end of the capacitor 62, and the other end of the capacitor 62 is connected to the power supply terminal 64B. The power supply terminals 64A and 64B are supplied with, for example, a DC voltage Vs generated by rectifying and boosting a commercial AC voltage, and the capacitor 62 is charged with the DC voltage Vs and accumulated when the flash lamp 48 emits light. Electrostatic energy is supplied to the flash lamp 48.

  The trigger electrode of the flash lamp 48 is connected to the trigger circuit 66. The trigger circuit 66 includes a transformer 68, and the trigger electrode of the flash lamp 48 is connected to the other end of the secondary coil 68B of the transformer 68 whose one end is grounded. One end of the primary side coil 68A of the transformer 68 is connected to one end of the resistor 70 and one end of the capacitor 72, and the other end of the resistor 70 is connected to the power supply terminal 74A. The other end of the primary coil 68A is connected to one end of the thyristor 76, and the other end of the thyristor 76 is connected to the other end of the capacitor 72 and the power supply terminal 74B. The capacitor 72 is charged by the DC voltage Eg supplied via the power supply terminals 74A and 74B, and when the thyristor 76 becomes conductive, the accumulated electrostatic energy is supplied to the trigger electrode of the flash lamp 48 via the transformer 68. As a result, the flash lamp 48 is caused to emit light.

  The gate of the thyristor 76 is connected to the collector of the transistor 78. The collector of the transistor 78 is connected to the power supply line via the resistor 80, and the emitter is grounded. The base of the transistor 78 is connected to the other end of the resistor 82 whose one end is grounded, and is connected to the control signal input end 86 via the resistor 84. The control signal input terminal 86 is connected to a lighting control circuit 88 including a microcomputer or the like. The lighting control circuit 88 supplies to the trigger circuit 66 via the control signal input terminal 86 a control signal that switches to a high level when the flash lamp 48 is turned off and switches to a low level when the flash lamp 48 is turned on. While the control signal is at the low level, the thyristor 76 is turned on by turning off the transistor 78, and the electrostatic energy accumulated in the capacitor 72 is supplied to the trigger electrode of the flash lamp 48 via the transformer 68. As a result, the flash lamp 48 emits light.

  The eight flash lamps 48 of the flash fixing units 46 and 47 are connected to the power circuit 58 and the trigger circuit 66, respectively. The trigger circuit 66 connected to each flash lamp 48 is a lighting control circuit. 88, respectively. The lighting control circuit 88 controls turning on / off of the eight flash lamps 48. The flash fixing unit 46, the power supply circuit 58 and trigger circuit 66 connected to each flash lamp 48, and the lighting control circuit 88 correspond to the flash fixing device according to the present invention, and the power supply circuit 58, trigger circuit 66 and lighting control. The circuit 88 corresponds to the driving means according to the present invention. Further, the four flash lamps 48A to 48D of the first flash fixing unit 46 are the first flash lamp according to the present invention, and the four flash lamps 48A to 48D of the second flash fixing unit 47 are the present invention. Each corresponds to the second flash lamp.

  On the other hand, winding rollers 56 and 58 are sequentially arranged at the subsequent stage of the winding roller 42, and the recording medium 12 on which the toner image is fixed by being irradiated with flash light from the flash fixing unit 46 is wound around. It is guided by rollers 56 and 58 and discharged out of the body of the color image forming apparatus 10. Although the color image forming apparatus 10 according to the present embodiment is configured to record a color image only on one side of the recording medium 12, two color image forming apparatuses 10 according to the present embodiment are prepared and the recording medium 12 is provided. 2 are prepared after the recording medium 12 on which the color image is recorded and discharged only on one surface by the first color image forming apparatus 10 is reversed by the inverter. If two color image forming apparatuses 10 and a reversing device are arranged so as to be fed into the body of the eye color image forming apparatus 10, a color image can be recorded on both surfaces of the recording medium 12.

  Next, the operation of this embodiment will be described. When the capacitance of the capacitor 62 of the power supply circuit 58 is changed, the magnitude of the electrostatic energy supplied from the capacitor 62 to the flash lamp 48 changes, as shown in FIG. As the capacity increases, the peak of the amount of flash light from the flash lamp 48 increases, and the period during which the flash light is emitted from the flash lamp 48 becomes longer. Accordingly, the recording medium 12 (toner image) is supplied. Energy to be changed. When the DC voltage Vs supplied to the power supply circuit 58 via the power supply terminals 64A and 64B (that is, the voltage supplied to the flash lamp 48) is changed, as shown in FIG. As the voltage Vs increases, the peak of the amount of flash light from the flash lamp 48 increases, and the energy supplied to the recording medium 12 (toner image) changes accordingly.

  In the present embodiment, energy (light emission intensity) α (shown in FIG. 2B) supplied to the recording medium 12 (toner image) when the four flash lamps 48 of the second flash fixing unit 47 emit light. (See the broken line pattern) is large enough to fix the toner image on the recording medium 12, and when the four flash lamps 48 of the first flash fixing unit 46 emit light, the recording medium 12 (toner More specifically, the energy β is 70 to the energy α, so that the energy (emission intensity) β (see the solid line pattern shown in FIG. 2B) supplied to the image) is smaller than the energy (emission intensity) α. The first flash fixing unit 46 and the second flash fixing unit 47 are connected to each flash lamp 48 so that the size is about 80% (β = 0.7α to 0.8α). At least one of the electrostatic capacity of the capacitor 62 of the power supply circuit 58 and the DC voltage Vs supplied to the power supply circuit 58 is different (specifically, connected to each flash lamp 48 of the first flash fixing unit 46). At least one of the electrostatic capacity of the capacitor 62 of the power supply circuit 58 and the DC voltage Vs supplied to the power supply circuit 58 is connected to each flash lamp 48 of the second flash fixing unit 47 rather than the power supply circuit 58. Small).

  When the color image forming apparatus 10 starts to record an image on the recording medium 12, the lighting control circuit 88 includes four of the first flash fixing units 46 as shown in FIG. The flash lamps 48 and the four flash lamps 48 of the second flash fixing unit 47 emit a control signal to the trigger circuit 66 connected to each flash lamp 48 so that each of the flash lamps 48 emits light for a predetermined time at a predetermined light emission period. Output. In the present embodiment, the light emission period of the flash fixing units 46 and 47 is based on the length along the conveyance direction of the recording medium 12 in the flash light irradiation range on the recording medium 12 when the flash lamp 48 is emitted. Corresponds to the time required for the recording medium 12 to be transported over a short distance.

  As shown in FIG. 2D, the flash fixing units 46 and 47 (each flash lamp 48 thereof) intermittently emit light at the above-described light emission period, so that the recording medium in each light emission of the first flash fixing unit 46 is obtained. The flash light irradiation range on the recording medium 12 partially overlaps at both ends along the conveyance direction of the recording medium 12, and the first flash fixing unit 46 intermittently emits light on the entire surface of the recording medium 12. A substantially uniform energy β is supplied. Further, the irradiation range of the flash light on the recording medium 12 in each light emission of the second flash fixing unit 47 also partially overlaps at both ends along the conveyance direction of the recording medium 12, so that the second flash fixing unit With the intermittent light emission of 47, substantially uniform energy α is supplied to the entire surface of the recording medium 12. Since the second flash fixing unit 47 is located downstream of the first flash fixing unit 46 in the conveyance direction of the recording medium 12, each part of the recording medium 12 is separated from the first flash fixing unit 46. After the flash light is irradiated and energy β is supplied, the flash light from the second flash fixing unit 47 is irradiated and energy β is supplied, and energy (α + β) is supplied in total. .

  As a result, the toner forming the toner image on the recording medium 12 is first melted at an increased temperature due to the energy β supplied by the flash light from the first flash fixing unit 46. Since the energy β to be applied is about 70 to 80% of the magnitude (energy α) sufficient to fix the toner image, the toner is only about 80% on the recording medium 12 as will be apparent from the experimental results described later. While the toner image is not fixed, voids or the like are not generated, and the toner component that causes the voids is removed by gradually vaporizing during this time. Subsequently, when the flash light from the second flash fixing unit 47 is irradiated, the toner on the recording medium 12 is sufficiently heated and melted by supplying energy α, and the entire amount thereof is converted into a toner image. It is fixed on the recording medium 12. At this time, since the toner component that causes voids and the like has already been removed, it is possible to avoid the occurrence of voids and the like as the temperature of the toner rises, and the toner image transferred to the recording medium 12 can be removed. It can be fixed as a high-quality image.

  The toner image on the recording medium 12 is a color toner image obtained by superimposing toner images of C, M, Y, and K colors (corresponding to the invention of claim 7), and the toner image is compared with a single color toner image. Since a large amount of toner is formed, a larger amount of energy is required to melt the entire amount of toner. As described above, the first flash fixing unit 46 emits light to supply energy β. The toner on the recording medium 12 is suppressed while the generation of voids and the like is suppressed by removing the toner component that causes voids and the like, and then supplying the relatively large energy α by causing the second flash fixing unit to emit light. An image (color toner image) can be reliably fixed. In addition, since the generation of voids and the like is suppressed, the amount of dust is also suppressed, so that the lifetime of the smoke removal filter (not shown) attached to the color image forming apparatus 10 can be increased.

  In the above, the flash fixing units 46 and 47 have the same light emission period, and the flash fixing unit is adjusted by adjusting at least one of the electrostatic capacity of the capacitor 62 of the power supply circuit 58 and the DC voltage Vs supplied to the power supply circuit 58. The energy supplied to the toner image by the flash light from 46 is smaller than the energy supplied to the toner image by the flash light from the flash fixing unit 47 (70 to 80%), but is not limited to this. For example, as shown in FIG. 5, the light emission period of the second flash fixing unit 47 is shorter than the light emission period of the first flash fixing unit 46 (for example, 1 / N (N is a natural number of 2 or more). )), The above-described energy difference may be caused.

  FIG. 5A shows an example in which the light emission period of the second flash fixing unit 47 is ½ that of the first flash fixing unit 46. Specifically, the second flash fixing unit 47 is shown in FIG. The light emission period 47 is ½ of the length of the irradiation range of the flash light on the recording medium 12 when the second flash fixing unit 47 emits light along the conveyance direction of the recording medium 12. Also, the time required for transporting the recording medium 12 over a slightly short distance is matched. As a result, as shown in FIG. 5B, each portion of the recording medium 12 is irradiated with the flash light from the second flash fixing unit 47 twice. Assuming that the energy supplied by one light emission is γ, the substantially uniform energy 2γ is supplied to the entire surface of the recording medium 12 by the flash light from the second flash fixing unit 47.

  In the aspect of FIG. 5, the energy 2γ supplied to each part of the recording medium 12 by irradiating each part of the recording medium 12 with the flash light from the second flash fixing unit 47 twice, for example, has been described above. The energy α can be equal to (γ = α / 2), but the second flash light is emitted from the second flash fixing unit 47 after the first flash light is irradiated on each part on the recording medium 12. The energy 2γ may be made larger than the energy α (γ> α / 2) in consideration of the temperature decrease of the toner until the toner is irradiated. In the aspect of FIG. 5, setting the energy 2γ supplied by the flash light from the second flash fixing unit 47 to a desired magnitude is supplied to the capacitance of the capacitor 62 of the power supply circuit 58 and the power supply circuit 58. This can be realized by using together adjustment of the DC voltage Vs (or adjustment of the number of flash lamps 48 for each individual flash fixing unit described below).

  It is also provided in each flash fixing unit that the energy supplied to the toner image by the flash light from the flash fixing unit 46 is made smaller than the energy supplied to the toner image by the flash light from the flash fixing unit 47. This can also be realized by making the number of flash lamps 48 different. For example, if the number of flash lamps 48 provided in the first flash fixing unit 46 is about 70 to 80% of the number of flash lamps 48 provided in the second flash fixing unit 47, the first flash fixing is performed. The energy supplied by the flash light from the unit 46 is set to about 70 to 80% of the energy supplied by the flash light from the second flash fixing unit 47, so that the capacitance of the capacitor 62 and the power circuit 58 are reduced. This can be realized without making the direct current voltage Vs and the light emission cycle different from each other.

  In the above description, the four flash lamps 48A to 48D of the first flash fixing unit 46 corresponding to the first flash lamp according to the present invention are caused to emit light at the same time, and also correspond to the second flash lamp according to the present invention. Although the example in which the four flash lamps 48A to 48D of the second flash fixing unit 47 emit light at the same time has been described, the present invention is not limited to this, and the flash lamp corresponding to the first flash lamp or the second flash lamp When a plurality of flash lamps corresponding to the flash lamps are provided, the light emission timings of some or all of these flash lamps may be made different without departing from the present invention.

  Furthermore, in the above, the first flash fixing unit 46 including the flash lamps 48A to 48D corresponding to the first flash lamp according to the present invention and the flash lamps 48A to 48D corresponding to the second flash lamp according to the present invention. However, the present invention is not limited to this, and light is emitted at a timing different from that of the first and second flash fixing units 46 and 47. One or more flash fixing units with flash lamps may be further provided. This flash fixing unit may be provided between the first flash fixing unit 46 and the second flash fixing unit 47, or further downstream of the second flash fixing unit 47 along the conveyance direction of the recording medium 12. May be provided. The present invention includes the above-described aspects within the scope of rights.

  Further, in the above, the flash lamps 48A to 48D corresponding to the first flash lamp are unitized as the first flash fixing unit 46, and the flash lamps 48A to 48D corresponding to the second flash lamp according to the present invention are the first. However, the present invention is not limited to this. For example, a flash lamp that functions as a first flash lamp and a flash lamp that functions as a second flash lamp are described. Alternatively, the first flash lamp and the second flash lamp may be arranged in a mixed manner, such as alternately arranged along the conveyance direction of the recording medium 12.

  In the above description, the example in which the present invention is applied to fixing of a color toner image has been described. However, the present invention is not limited to this, and it is needless to say that the present invention can also be applied to fixing of a monochrome toner image.

  Next, an experiment conducted by the present inventor will be described. In order to confirm the optimum value of the energy supplied by the flash light from the first flash fixing unit 46, the inventor of the present application checks the emission intensity of the flash light from the first flash fixing unit 46 (energy supplied to the toner image). ) Is changed stepwise to irradiate only the flash light from the first flash fixing unit 46 to the unfixed color toner image (color toner image not irradiated with flash light) on the recording medium 12. An experiment was conducted to confirm how the fixing property and the occurrence of voids change.

  The fixability of the toner image is determined by measuring the density D of the image (toner image) on the recording medium 12 irradiated with flash light and applying the tape to the recording medium 12 irradiated with flash light with a certain pressure. 12, the density D ′ of the image (toner image) after the tape was peeled off was measured, and the image density ratio D ′ / D obtained by calculation from the measurement result was used as an index of toner image fixability. FIG. 6A shows the relationship between the light emission energy of the flash light of the first flash fixing unit 46 obtained by this experiment and the fixability of the toner image. As is clear from FIG. 6A, the fixing property (image density ratio) is 100% in the range where the light emission energy is α or more, and the toner image is formed by the flash light from the second flash fixing unit 47. It can be understood that the energy to be supplied can be supplied to the toner image by setting the energy to α in FIG. 6A to fix the toner image.

  On the other hand, the supply of energy by the flash light from the first flash fixing unit 46 is mainly intended to remove the toner composition that causes the voids without causing the voids. In order to remove the toner component, the toner is heated to start melting, and the melted toner needs to be fixed to the recording medium 12 as a toner image to a certain extent (for example, about 80%). . In FIG. 6A, the emission energy for obtaining 80% fixability (image density ratio) is 0.7α, and the first flash fixing is used to remove the toner composition that causes voids and the like. The energy supplied to the toner image by the flash light from the unit 46 needs to be 0.7α or more.

  FIG. 6B shows the relationship between the emission energy of the flash light of the first flash fixing unit 46 obtained by the above experiment and the degree of generation of voids. As shown in FIG. 6B, no void is generated when the light emission energy is 0.6α or 0.7α. However, when the light emission energy is 0.8α, a void that cannot be visually confirmed can be confirmed using a magnifying glass. It was found that a slight void was generated, and a void that could be visually confirmed was generated when the emission energy was increased to 0.9α. For this reason, in order to prevent the generation of voids, the energy supplied to the toner image by the flash light from the first flash fixing unit 46 needs to be 0.8α or less.

  Therefore, from the result of the above experiment, the energy β supplied to the toner image by the flash light from the first flash fixing unit 46 is set to 70 to 80% (β = 0.7α to the energy α at which 100% fixability is obtained. 0.8α), it is possible to remove the toner composition causing the voids without causing a significant void by the flash light from the first flash fixing unit 46, and then the second flash fixing unit. It has been clarified that if the energy of α or more is supplied by the flash light from 47, the toner image can be reliably fixed to the recording medium 12 without causing voids or the like.

1 is a schematic configuration diagram of an image forming apparatus according to an exemplary embodiment. (A) is a schematic diagram of the flash fixing unit, (B) is a diagram showing the light emission intensity of each of the first and second flash fixing units, and (C) is a light emission timing of the first and second flash fixing units. A timing chart showing an example, (D) is a diagram showing a distribution of integrated values of energy supplied to a recording medium (toner image). It is a schematic block diagram of a flash lamp drive system. (A) is a diagram showing the relationship between the capacitance of the capacitor and the change pattern of the irradiation light amount, and (B) is a diagram showing the relationship between the applied voltage and the change pattern of the irradiation light amount. (A) is a timing chart showing another example of light emission timing of the first and second flash fixing units, and (B) is an integrated value of energy supplied to the recording medium (toner image) in the example of (A). It is a diagram which shows distribution. (A) is a diagram showing the relationship between the light emission energy of the fixing unit and the fixability of the toner image, and (B) is a graph in which the light emission energy of the fixing unit is changed to explain the results of experiments conducted by the inventors. It is a graph which shows the determination result of the void generation condition at the time. It is an image figure which shows an example of a void.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Color image forming apparatus 12 Recording medium 46 Flash fixing unit 47 Flash fixing unit 48 Flash lamp 58 Power supply circuit 62 Capacitor 66 Trigger circuit 88 Lighting control circuit

Claims (6)

First and second flash lamps that emit flash light for fixing the toner image transferred onto the recording medium;
The first flash light emitted from the first flash lamp is irradiated to each portion on the recording medium onto which the toner image to be fixed has been transferred, and then the second flash lamp emitted from the second flash lamp. The first and second flash lights are irradiated, and the energy supplied to the toner image by the first flash light is smaller than the energy supplied to the toner image by the second flash light. Drive means for emitting two flash lamps;
Including flash fixing device.   The driving unit causes the first flash lamp to emit light so that energy supplied to the toner image by the first flash light has such a magnitude as to start melting of the toner. The flash fixing device according to claim 1.   The drive means controls the first flash lamp so that the energy supplied to the toner image by the first flash light is 70 to 80% of the magnitude α sufficient to fix the toner image. The flash fixing device according to claim 1, wherein the flash fixing device emits light.   The drive means differs in the number of flash lamps that emit light as the first flash lamp and the number of flash lamps that emit light as the second flash lamp, thereby providing energy supplied to the toner image by the first flash light. 2. The flash fixing device according to claim 1, wherein the energy is made smaller than energy supplied to the toner image by the second flash light.   The driving means makes at least one of a voltage supplied to the flash lamp, a capacitance of a capacitor connected in parallel to the flash lamp, and a light emission cycle different between the first flash lamp and the second flash lamp. 2. The flash fixing device according to claim 1, wherein energy supplied to the toner image by the first flash light is made smaller than energy supplied to the toner image by the second flash light. .   2. The flash fixing device according to claim 1, wherein the toner image to be fixed is a color toner image obtained by superimposing a plurality of color toner images.

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